ARMY  MEDICAL  LIBRARY

          WASHINGTON

              Founded 1836
Section.
Number J.7...(a..9.9.^....
              Form 113c, W. D., S. G. O.
BfO   3—10543     (Revised June 13, 1936) 
 
 
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   DAVIS'S MANUAL
            OF

MAGNETISM.
j^H^H^H^t^H^^^^ 
V*
  The frontispiece consists of two copper-plate engravings, one print-
ed from an engraved plate, and  the other from an electrotype  copy
taken from it in the mode described on page 51.  The engravings
are introduced for the purpose of showing the accuracy of the copies
obtained by this process. 
 
MtJ-UIZS'.U. PLATE. 
 
 
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A
MANUAL  OF  MAGNETISM,
INCLUDING
1
GALVANISM, MAGNETISM,--ELECTRO-MAGNETISM,
 ELECTRO-DYNAMICS, MAGNETO-ELECTRK ITY,
       AND THERMO-ELECTRICITY
WITH 180 ORIGINAL ILLUSTRATIONS.
             S.i 1 I> IP ft-. Jtl.- 1
         ; 3lJf*G€ON,'GENlEf?AL,S0F'F!Cr
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                      i
          BOSTON:
PUBLISHED  BY DANIEL DAVIS, JR.,
    MAGNETICAL INSTRUMENT MAKER,
       428 Washington Street.
           1847. 

Entered according to act of Congress, in the year 1847,
              By DANIEL DAVIS, JR.,
 In the Clerk's office of the District of Massachusetts.
 
PREFACE.
  Tare present work is  principally  occupied with  Mag-
netism in its connection with  Electricity.  But the gen-
eral  phenomena of both  these sciences are described  as
fully as the thorough comprehension of the relations  ex-
isting between  them  appeared to require.  It has  been
the aim  to give to the  book  a  practical, rather than a
theoretical character,  and  to introduce  hypotheses  no
further  than was essential  to a  clear  explanation  of the
phenomena  described.   Many important observations and
results connected  with  magnetism  and  electricity have
never been brought  together in any scientific work; and
the  present  volume, though  mainly intended  as  a com-
panion  to the  apparatus  manufactured  by me, has,  in
consequence,  taken  the  form  of  a  treatise  on  those
branches  of science to  which  it  relates, and  may  be
used  as  a  text-book.
   Since  the  appearance  of  the  first  edition  of this
Manual,  in 1842, some progress has  been made  in  the
departments  of science  treated  of, and  many new and
                 1* 
VI
PREFACE.
improved  instruments  have been  contrived  to illustrate
them.  In  preparing  a new edition, alterations  and  ad-
ditions have  been made,  to adapt it  better to  the  pur-
poses of  a text-book for Colleges and  High Schools, and
also  as a  companion  to  the  apparatus.   The  Manual
has for some years been  in use  as a text-book, for the
sake of its demonstrations, in the  United States' Military
Academy  at  West.'Point.
  The preparation' of the present,  as well  as of  the
former edition,  has  been  principally  under  the charge
of Drs.  John  Bacon,  Jr., and William  F.  Channing.
The arrangement which  has  been adopted,   and which
differs  from that  of any previous  work, is  founded upon
a natural order; and  the  attempt has  thus  been  made
to establish a more  scientific  relation  between  the  facts
of magnetism.    Many of  the instruments and experi-
ments  are  original,  and  are   now  for the  first   time
described.    Among  the   new  articles  of apparatus,  a
considerable  number  have  been  contrived  or improved
by Mr. E. B. Horn.   Numerous   wood  cuts  are  intro-
duced  to  illustrate the subjects  under  consideration.

                               Daniel  Davis,  Jr.
Boston,  August, 1847. 
CONTENTS.
                INTRODUCTION.
                                            Page
DEFINITIONS AND EXPLANATIONS,...................  1

         PRODUCTION OF  ELECTRICITY.
 1. FRICTIONAL ELECTRICITY,........................  7
 2. GALVANIC ELECTRICITY,..........................  8
 3. THERMO-ELECTRICITY,............................. 67
 4. ANIMAL ELECTRICITY,.............................. 82


               MAGNETISM.

                   BOOK I.

    DIRECTIVE TENDENCY OF  THE MAGNET.
 1. IN REFERENCE  TO ANOTHER  MAGNET,.......... 89
 2. IN REFERENCE TO A  CURRENT OF ELECTRICITY,. 94
 3. IN REFERENCE TO THE EARTH,..................130 
Vlll
CONTENTS.
                     BOOK  II.

           INDUCTION OF MAGNETISM.
                                                Page  i  i
1. BY A  MAGNET,....................................  139  »  '
2. BY A CURRENT OF ELECTRICITY,................  159  '  i
3. BY THE  EARTH,...................................  223  i  :


                    BOOK III.

          INDUCTION OF ELECTRICITY.
1. BY A CURRENT OF  ELECTRICITY,...............  227
2. BY A  MAGNET,....................................  264
3. BY THE  EARTH,...................................  306 
     DEFINITIONS AND EXPLANATIONS.

   1. Magnetism. — The term magnetism expresses
the peculiar properties of attraction, repulsion, &c,
possessed, under certain  circumstances, by iron and
some of its compounds, and in  a somewhat  inferior
degree by nickel, a closely-allied metal.  Cobalt is
perhaps slightly magnetic.
   Electro-Magnetism. — That branch  of  science
which  relates  to the development of magnetism by
means  of a current of electricity,  is called electro-
magnetism.   It will  be treated of in  Book  I.
Chapter 2,  and in Book II. Chapter 2.
   Magneto-Electricity treats  of the development
of electricity  by the  influence  of  magnetism, and
will form the  subject  of Book  III.  Chapter  2.
   2.  Magnet. — The  body which exhibits magnetic
properties is called a magnet.  This name is confined
to the metallic  substances mentioned above; but all
conductors  of  electricity are  capable of exhibiting
similar attractions  and repulsions while conveying
a current.
           1 
2              davis's  manual.

  Natural  Magnets. — Certain  ores of  iron  are
found  to  be possessed of the magnetic properties in
their natural state.   These are called natural mag-
nets, or loadstones.
  Artificial  Magnets. — Bodies belonging  to  the
magnetic  class,  in  which magnetism is  artificially
induced, are  called  artificial magnets.

  3. Induction  of Magnetism. — Whenever mag-
netic   properties  are developed  in bodies  not  pre-
viously possessed of them, the process is termed the
induction  of magnetism.    When  this  is effected by
the influence of a  magnet,  it is  called magnetic in-
duction;  when  by a current  of electricity,  electro-
magnetic induction.
  Induction of  Electricity. — This term express-
es the development of electricity by the influence
of other electricity in its neighborhood,  or by  the
influence  of magnetism.   In  order  to distinguish
the inductive action of an electric current  from the
static  induction of  electricity at rest, the  former is
called  electro-dynamic induction.    The development
of electricity by  the influence of a magnet is termed
magneto-electric induction.

  4. Poles. — The magnetic  phenomena  manifest
themselves principally at the two  opposite extrem-
ities of the  magnet; the force of  the  attractions and
repulsions diminishing rapidly as  the distance from
them  increases, until  it becomes entirely insensible
at the  middle  point.  These extremities are called
the poles  of the  magnet. 
EXPL AN ATI ON S .
3
  5.  The earth  itself is  found to possess  the prop-
erties of  a magnet,  having  magnetic  poles  corre-
sponding nearly in their direction with the poles of
its  diurnal rotation.  Now,  if a straight magnet be
suspended  so as to allow of a free horizontal  mo-
tion,  it  will be found  to  place itself in a direction
nearly north and south;  as  will  be explained here-
after.  The end which  turns towards the  north  is
called the north pole of the  magnet, the other  end
its  south pole.   Hence every magnet, whatever its
form, is said to  have a north and a south  pole.   In
the figures  to be hereafter described, the north  pole
is indicated  by the point  of  an arrow, and  the south
pole by  the feather; or  by the letters N and S re-
spectively.   The  poles of a  galvanic  battery  will
be  described  farther  on,  when  treating  of  that
instrument.

  6.  Permanent  Magnets. — It  is  found that  pure
soft iron easily acquires  magnetism when  exposed
to  any  magnetic  influence, but  immediately loses
this magnetism when that  influence is  withdrawn.
But steel, which is a compound of  iron with a small
quantity of carbon,  and  especially hardened  cast-
steel, though it acquires the magnetic properties less
readily, retains  them more or less permanently after
they  are  acquired.   Hence  a  magnet formed of
hardened steel  is called a permanent magnet.

  7.  Bar Magnet.—An  artificial permanent magnet,
in the form  of a straight bar, is called a bar magnet. 
4
DAVIS'S  MANUAL.
               Fig. l.              Fig.  1 represents
                                a small  case, con-
                                taining  two  bar
                                magnets, with two
                                short pieces of soft
                                iron    connecting
                                their  poles:  these
act as  armatures  (see § 9),  and serve  to preserve
the power of the magnets.   The magnets, when not
in use, should be kept packed in the case, with their
opposite  poles  connected by the armatures,  in the
manner shown in the cut.
  Compound  Bar Magnet. — A magnet  composed
of several straight bars joined together, side by side,
with their similar poles in  contact, for the purpose
of increasing the  magnetic  power, is called  a com-
pound  bar magnet.
                       Fig. 2.
  Such a magnet,  composed of three simple mag-
nets, fastened together, is represented in Fig. 2.
 Fig. 3.
           8.  Horseshoe  or U-Magnet. — A mag-
        net which is bent into  such a  form as to
        bring the two opposite poles near together,
        so that they can be  connected by a short,
        straight  piece of iron, is called  a horseshoe
        or U-magnet.
           Fig. 3 represents  a steel magnet of this
        desciption.
 
E xplanat ions.
5
              Compound Horseshoe Magnet.—A
            magnet composed of several  horseshoe
            magnets joined  together, side by  side,
            as in  Fig.  4,  for the  purpose of in-
            creasing the power, is called a compound
            horseshoe  magnet,  or  magnetic battery.
            These magnets  are  charged  separately,
            and are put together with all the similar
            poles in the same direction.

  9.  Armature.—A  piece of soft iron, adapted to,
and intended  to  connect the poles  of a magnet, is
called  an armature, or keeper.   Horseshoe  magnets
are  usually provided with  an armature,  consisting
of a  straight  bar  of iron,  for the  purpose of pre-
serving their  magnetic power:  this  should  be  kept
constantly applied to the poles of the magnet  when
it is not in  use;  as shown in Fig. 4, where A is the
keeper.  Armatures are employed in various experi-
ments, and their forms vary with the purposes intended.
          Fig. 5.
                             10. Magnetic Needle.
                           — A light  and slender
                           magnet,  mounted upon a
                           centre of motion,  so as
                           to allow it  to  traverse
                           freely in certain direc-
                           tions, is called a  mag-
                           netic needle.   It may be
                           so mounted as to  move
                           only  horizontally, as in
                           Fig.  5;  or  its motion
Fig. 4.
 
6
D AVIS ' S  MANUAL.
    Fig- 6.    may be  confined  to  a vertical  direc-
             tion, as shown in Fig. 6.   This  last
             form is called a  dipping  needle.   By
             means  of a universal joint, the needle
             may be supported in such a manner as
             to have freedom  of motion  in both a
horizontal and vertical direction.

   11.  The  most obvious effects exhibited by mag-
nets  are  their power  to  attract  iron,  and their
tendency, when freely suspended,  to assume a de-
terminate position in reference to the earth.  For a
long time, these were the only properties which were
noticed, or at least which received  particular atten-
tion.   The  attractive  power of  the loadstone over
small pieces of iron seems to have been known from
the remotest antiquity; but its polarity  with regard
to the earth does not appear to have been observed,
at least  in  Europe,  until the  eleventh  or  twelfth
century of the Christian era.  It is,  however, stated,
by a distinguished orientalist, M. Klaproth, that the
Chinese  were  acquainted with the  polarity of the
magnet, and employed  it as a  guide  to travellers
on  land, at least as  early as the  second century j
also, that the use  of the mariner's compass  in nav-
igation  originated with  them, and  was  communi-
cated to the European nations through  the  Arabs.
 
FR1CTI0NAL   ELECTRICITY.      7
        PRODUCTION OF  ELECTRICITY.


   12.  As  a current  of  electricity is requisite  in
many  of the  experiments to  be  mentioned  here-
after, it becomes  necessary to describe  the various
means by  which  it may be  produced.

  I.  MECHANICAL OR FRICTIONAL ELECTRICITY.

   13.  The  electricity developed by  the electrical
machine is called mechanical or frictional, from the
mechanical force or friction by which  it  is obtained.
It possesses properties differing  much in degree from
those exhibited by the galvanic  arrangements de-
scribed below, and is far inferior in producing mag-
netic effects, which  require an  electric current.  On
the other hand,  it greatly surpasses  galvanic elec-
tricity in exhibiting the phenomena of electricity at
rest, under  its  two forms  of positive and negative.
   14.  The great development of electricity observed
during  the  escape of steam from high pressure boil-
ers, may be mentioned here.   This is collected for
purposes of experiment, by plunging into  the  steam,
escaping from the safety valve, a brass rod  (Fig.  7) 
8
D A VI S ' S  MANUAL.
furnished  with a brush of points, P, at  one end,
collect the electricity, and held by means of an
                      Fig. 7.
sulating handle attached to the other end.   A length
of six or  eight  feet is found advantageous,  in  this
instrument,  to convey and  insulate the electricity,
which may be conveniently drawn from the lower
part of the rod.   In the cut, the  brass rod is repre-
sented as terminating in a brass ball, B, insulated from
the wooden handle, H, by a stout  glass rod, G.
   15. The  electricity obtained in this  way  from
steam is of high  intensity, affording sparks of an inch
or more in length, and charging  the  Leyden jar so
as to give strong shocks.  It is almost always  posi-
tive,  and is not obtained unless  the steam is of high
pressure, so as to issue from the valve  as a trans-
parent vapor.

    II.  GALVANIC OR VOLTAIC  ELECTRICITY.

   16. These  names are given to that form of elec-
tricity which  is  produced by  chemical  action.  It
is found that,  when two metals are placed in contact
with each  other, and  with some  liquid  capable of
acting upon one more than upon the other, electricity
of a  peculiar  character is developed.   The peculiar
electrical relation of the metals employed, also exerts
an influence  upon this result.   The metals  most 
          GALVANIC  ELECTRICITY.          9

extensively used  are  zinc  and copper, or zinc and
platinum;  and  the  chemical  agent is some liquid
containing  an acid having a powerful affinity for
zinc.   The language  adopted in describing  the re-
sulting  phenomena  was founded  originally on  the
supposition that electricity  is given out to the copper
from the zinc, which  is corroded, through the liquid
      Fig.  8.      between them.  This is shown in
                  the  adjoining  cut (Fig. 8), which
                  represents  a glass vessel,  nearly
                  filled with the fluid, and contain-
                  ing  a  zinc  plate,  marked  Z, and
                  one of copper, C.   Now, the  sup-
                  posed motion  of the electric cur-
                  rent within  the  vessel,  is from Z
                  to C;  and  if the two  metals are
                  connected by  a wire without  the
                  vessel, as in the  cut, in order to
                  fulfil  the  condition of  metallic
                  contact, the electricity is supposed
                  to pass around through the wires
from the  copper to the zinc again, to restore  the
equilibrium of the fluid.  Thus the current  is  con-
sidered  as  passing  from zinc to copper  within  the
series,  and  from  copper to  zinc  without  it.   The
wire connected with C is called the  positive pole of
the arrangement, and  that with Z the  negative pole.
   17.  The electricity proceeding  from the positive
pole is the same in  its relations  as the  electricity
from the prime conductor of the electrical machine,
which  originally received the name of positive; while
 
10            DATIS's  -.-.
 that  from  the  negative pole corresponds with the
 electricity obtained  from the rubber of the machine.
 These terms  are, however, to a certain extent, arbi-
 trary.   It  is still an open question, whether there is
 one fluid moving in a  particular  direction,  or two
 fluids moving in opposite directions,  or no  motion
 of a fluid  at  all.   The fact which is sought  to be
 explained  by these  theories remains  fixed.   In the
 above-described  circulation  of  the electrical  fluid,
 technically called the galvanic circuit, there is an
 electrical influence  propagated  in  a certain unchan-
 ging direction;  and  as  the  control of the  magnetic
 and chemical reactions  produced depends upon our
 knowledge  of this,   it  is necessary that  the signi-
 fication  of the  terms should be understood.
   18.  Professor  Faraday has proposed a nomencla-
 ture of electricity, which has been adopted in  some
 scientific treatises.   The poles are called by  him
 electrodes, from  the  Greek  ^Xsxrpcv and I86s'} that is,
 ways or paths of electricity ;  the  positive pole the
 anode, from the Greek avoSog, an ascending  or enter-
 ing way, and the  negative pole  the   cathode,  from
 the Greek  xu6o5os, a  descending way or path of exit.
 The terms  positive  and  negative pole  are, however,
 still  most  frequently employed to designate  these
 extremities, and the wire without, when  in connec-
 tion  with these poles, is  spoken of as the channel
 of a positive  current passing  from the former to
 the latter.
  19. Instead  of using  two  metals   to  form  the
galvanic  circuit, one metal,  in  different states,  may 
        QUANTITY  AND  INTENSITY.        11

be used on  the  same  principle ;  the  essential  con-
dition of this current being only  that one part of a
conductor  of electricity shall be  more corroded by
some chemical agent than another part.   Thus, if a
galvanic pair be  made of the same metal, one part
of which shall be softer than another,  as of cast and
rolled zinc, so as to  be differently corroded,  or  if
a greater amount of  surface be exposed to corrosion
on one  side  than on the other,  or a more powerful
chemical agent be used on one side, a current will
be determined from the part most corroded through
the liquid  to the part  least corroded,  whenever the
circuit of the poles  is  completed.
  20.  Galvanic  electricity  is capable  of producing
the most extensive magnetic, chemical, and calorific
effects.   In this respect, it has a far greater capacity
than mechanical  electricity, though it is found that,
by the  accumulation of this latter, the same effects
can  be  produced in  proportion to the amount pres-
ent.   This has led  to the  natural  inference, that,
in galvanic  electricity, the quantity present is im-
mense,  while in  mechanical,  the  quantity is small.
On the other hand,  it  is  found  that, in the  latter
form, the  electricity  is much more  energetic  in  its
physical reactions; that it appears to  be condensed
upon insulated   matter,  and  strives  to  obtain  an
equilibrium by diffusion in every direction.   It  is,
therefore, said that  mechanical  electricity has more
intensity than galvanic, though it is difficult to assign
other than a general idea  to this  word.  Owing  to
this  difference of intensity,  the substances,  such 
12
DAVIS'S  MANUAL.
as glass, earthen ware,  wood, ivory,  which act as
non-conductors  to  galvanic  electricity,  are much
more  numerous than the corresponding class, with
reference  to  mechanical  electricity.   A  true  com-
parison between these two forms of electricity, would
be made between the galvanic current and a  cur-
rent of  mechanical electricity, freely circulating, as
through a wire connecting the prime conductor  and
the rubber of an electrical machine.   So compared,
the fluid  would  be  found in both  identical in its
effects, with  scarcely greater  difference in  the  con-
ditions of  quantity and  intensity than we are  able
to produce by different  arrangements of  galvanic
series.
  21.  There  are two  modes  by which the peculiar
powers of a galvanic arrangement may be increased —
first, by increasing the size of the plates used;  and,
secondly,  by increasing  their number.  1.   The ex-
tension of the size of the plates.   If the  size of the
plates, that is, the extent  of the  surfaces acted upon
by  the  chemical agent,  is increased,  some of  the
resulting effects become  more powerful in  the same
ratio,  while others do  not.   The power to develop
heat and magnetism is increased, while the power
to decompose  chemical  compounds and   to affect
the animal system is very slightly, or not at all,  aug-
mented.   Batteries constructed in this way, of large
plates, are sometimes called calorimotors, from their
great  power  of producing  heat; and  they usually
consist of from one  to eight  pairs of plates.  They
are made  of  various forms.   Sometimes the sheets 
         QUANTITY  AND  INTENSITY.      id

 of copper and zinc are coiled in concentric spirals,
 sometimes  placed side  by  side;  and they  may be
 divided into a great number of small plates, provided
 that all the zinc plates are connected together, and
 all the  copper plates together, and then, finally, tnat
 the experiments  are  performed in a channel of elec-
 trical communication opened  between the  one con-
 geries and  the other;  for it  is immaterial whether
 one large  surface be  used,  or  many small surfaces,
 electrically connected  together.   The effect  of all
 these arrangements, by which the  metallic surface of
 a single pair is augmented, is to increase the quantity
 of the electricity produced. — 2.  The extension of the
 number  of the plates consecutively; that  is, by con-
 necting  the  copper  plate of each  pair with the zinc
 plate of the  next pair.   By this arrangement, the
 electricity is  obliged to traverse a longer or shorter
 series of pairs; each  pair being  separated from the
 adjoining ones by a stratum of imperfectly conduct-
 ing liquid,  or by the  walls  of an  insulating cell.
 The result is, that  the electricity acquires that ad-
 ditional impulse, which  has  already been referred to,
 as  intensity.   It  has  greater power  to pass through
 imperfect  conductors,  or through intervals  in the
 circuit,  to give  shocks  to the animal  system,  and
 to decompose  chemical  compounds;  and when the
 number of consecutive pairs of plates is increased to
 some  thousands,  or  even hundreds,  the  electricity
developed approaches very near in its  character to
that produced by the electrical machine; it manifests
similar  attractions and  repulsions, and in  fact  the
                2 
14             DAVIS'S  MANUAL.

Leyden jar may be charged  with it.   With a very
extensive series excited by water only,  and in which
each cell was  carefully insulated,  an  English elec-
trician  has lately  obtained  an electrical  discharge
between  the  poles,  although  separated  to  a con-
siderable distance.   The electricity from one pair of
plates has  a very low intensity.  As the number of
consecutive pairs  is  multiplied,  the  intensity  in-
creases, until  at  length it approximates to  that of
frictional electricity, which is  able to  strike  across a
considerable interval of air, and to fracture solid non-
conductors interposed  in  its circuit.
  22.  In  consequence of the  low intensity of the
electricity required for electro-magnetic experiments,
it is  very  easy  of insulation.   This  is a great ad-
vantage in regard to  the practical  construction of
magnetic  apparatus.   Where  electricity  exists in a
state  of high  intensity, it has a strong tendency to
pass off and  dissipate itself through  imperfect con-
ductors ;  but  where it exists only in great quantity,
it requires nearly  perfect conductors  to  allow it  a
passage.   The electricity developed by a single  pair
of plates,  however much  its  power may be increased
by increasing the size of the plates, will scarcely  pass
across the smallest interval of air;  and a wire con-
veying the current  may  be  perfectly  insulated by a
covering of varnish.   In  working  the  electrical  ma-
chine, on  the  other  hand, the  electrified parts  of the
apparatus must be kept at a distance from each other,
raised on glass supports, or suspended by silken lines;
and then,  unless  the atmosphere is  very dry,  the 
SMEE's  BATTERY.
15
electricity will be rapidly dissipated.  But in the case
of currents  of low intensity,  however  great what is
called the quantity may be, two wires may lie side by
side, with a coating of varnish or wax between them,
and  convey different and opposite currents, without
any  perceptible  electrical intercommunication.
  23.  For  the  purposes of electro-magnetic experi-
ments, electricity of a low intensity is  required ;  the
power of the magnetic  effects  of a current of elec-
tricity depending upon an increase of  its  quantity,
mainly.   Increasing the number of consecutive pairs
would only add  to the intensity of the current, making
it more unmanageable in respect  to insulation,  with-
out adding  much  to  its magnetic effects.  Galvanic
batteries having many  pairs  of plates are therefore
unsuitable  for  these experiments.  The maximum
magnetic effect is produced by a single galvanic com-
bination,  or at  most  by five  or six. In  some of the
reactions, however, of a magnet with  a coil  or elec-
tric  current, as well as  in experiments on  decompo-
sition and deflagration, batteries capable of producing
intense currents are  required.   The most convenient
forms of single pairs and of series will therefore now
be described.
  24.  Smee's  Battery. — This form will be first
             spoken of,  as furnishing an  example of
             the galvanic  battery in its  most simple
             form, as it has  been already illustrated
             in  Fig.  8.  It consists of a glass tum-
             bler, or other receiving vessel,  on which
             a little frame rests, supporting  the  appa-
             ratus within.    The  metals  employed
 
16
DAVIS'S  MANUAL.
are platinum  and  zinc.  The  original  battery  of
Smee consisted of zinc, and silver covered with a film
of platinum; but the metal platinum  itself is found
so much superior to the platinized silver, and the dif-
ference  in  expense so  slight, that it has been substi-
tuted.   The arrangement, also, as shown in the fig-
ure, has been modified from the original form.  The
metal platinum is used in this case, as it is the least
oxidizable  of the metals, and  therefore capable of
producing  a more powerful  current  with zinc* than
any  other.   On the frame  will  be seen two screw-
cups  for  the  attachment of  wires  by which  the
current may  be conveyed in  any  direction.  One
of these screw-cups communicates  with a strip of
platinum foil, which is suspended between two zinc
plates, both of the  surfaces of  the  platinum  being
opposed  to the zinc.   The amount  of galvanic  ac-
tion is  generally  in proportion to the metallic sur-
faces of different kinds opposed to each other, and
also  in  proportion to the nearness of those  surfaces.
The  other screw-cup  is connected with  both  the
zinc plates, thus uniting  them  into a single element
of the  pair.   The  screw-cup  connected  with  the
platinum  is insulated from the metallic  frame which
supports it, by rosewood; and a  thumb-screw, seen
at the left, confines or  releases the  zinc  plates, so
that they  can  be renewed  from time  to time.
   25.  The  liquid  used  to  excite  this  battery is
sulphuric acid (oil  of vitriol),  diluted  with  ten or
twelve parts of water by measure.  This acid acts on
common zinc when the galvanic circuit is not  estab- 
smee's  batte ry.
17
lished, and  a great loss would therefore ensue  from
the corrosion of the plates during the interval of ex-
periments, even if the zinc was withdrawn from the
acid whenever practicable.   To  remedy this defect,
it  has been  found that zinc  which  has  its surface
amalgamated  (or  combined  with  mercury)  with-
stands the action of diluted sulphuric acid, unless it
is  in  galvanic  connection with  another metal; and
accordingly the  zinc of  this battery, and of  other
batteries in which acid  is used, is commonly amalga-
mated.   It then remains almost uncorroded until the
galvanic  circuit  is  completed  by making  contact
between  the  wires, when  the  zinc  is immediately
attacked.   The amalgamation of the zinc is  easily
effected  by rubbing  it with  a little mercury and
muriatic acid at the same time.   This battery, when
once  in action, is very constant.  It  does  not,  how-
ever,  like the batteries  hereafter to  be  described,
arrive instantly at its highest rate of action when the
circuit is completed, but takes an  appreciable time to
reach this point, and  it is not therefore fitted for use
with  apparatus where the  circuit is  rapidly broken
and  renewed.   No adequate  increase of  power  is
obtained by  adding to the size  of this  battery.
   26.  In order  to understand  some  of  the  phe-
nomena  which  will  be  spoken  of  hereafter,  it  is
necessary to notice what takes place when the cir-
cuit  of the battery is  completed and the galvanic
current begins to flow.  The first thing which  is
observed  is  a rapid evolution of  gas in bubbles from
the platinum  plate.  It was  stated that  electricity
                2* 
18
D A VI S ' S  MANUAL.
was supposed to pass through the liquid between the
plates in a direction  from the zinc to  the  copper or
platinum.  This passage of electricity through fluids
which are not  themselves elementary, is attended
always, according to Faraday,  with decomposition,
whether  the  fluid is  between the plates of the bat-
tery or interposed in the course  of the wires or poles
leading from it.  Thus, where  a battery  is excited
simply by water, that fluid is decomposed;  its oxy-
gen attacks the zinc, and  its  hydrogen is given off
in contact with the electro-negative metal.
  27.  In Smee's battery, the  water of the acid
solution  may also be considered  as undergoing de-
composition,  one atom of its oxygen uniting with
one atom of zinc, in order to enable the sulphuric
acid  to unite with  the  resulting oxide of zinc,  and
the corresponding atom of hydrogen being given off
in contact with the platinum.  It will be observed
that the oxygen and hydrogen appear at the  opposite
sides  of  the  fluid undergoing decomposition.   It  is
not,  however,  believed  that  these elements  travel
through  the intervening distance, but that  the  two
atoms of water in contact  with  the  plates are  simul-
taneously decomposed, and that a  chemical equilib-
rium  is then established by a progressive exchange
of elements in all the intervening particles.  The sub-
ject  of electro-decomposition will be further spoken
of in connection with the electrotype.
   28.  The gas which  is  so plentifully  disengaged
at the surface of the platinum in this battery is apt  to
bring the strip into  contact with the  zinc, and thus 
    SULPHATE  OF  COPPER  BATTERIES.  19

cause a discharge between the metals within the bat-
tery, instead of through the poles without.   To obvi-
ate this, the platinum is either confined in its proper
position by some fixture at the  bottom, or  a bead of
glass  is attached to it, which prevents its  swinging
against the  zinc.
                                    Fig.  10 repre-
                                  sents a  series  of
                                  three pairs of this
                                  battery,  in which
                                  it will be observed
                                  that the platinum
                                  of one is connect-
                                  ed  with the  zinc
                                  of  the  next, and
that the terminal wires  proceed,  consequently,  one
from  a platinum  plate  and  the  other from  a  zinc
plate,  as in a single pair.
   29.  Cylindrical Sulphate  of Copper  Battery.
— This battery, a vertical section of which is rep-
                             resented  in  Fig.   11,
                             consists  of  a  double
                             cylinder of copper,  C C,
                             with  a bottom  of the
                             same metal;  which an-
                             swers the purpose  both
                             of a galvanic plate  and
                             of a vessel  to contain
                             the  exciting  solution.
                             The space between the
two copper  cylinders receives the solution.  There
 
20
DAVIS'S  MANUAL.
is a  movable  cylinder of  zinc, marked Z  in  the
sectional view, which  is let  down into  this solution
whenever the battery is to be put in action.   It  is,
of course, intermediate in size, as well as in  position,
to the  two  copper cylinders,  and is  made to rest
upon  the exterior one  by  means  of three insulating
branches of wood  or  ivory, projecting  from it  out-
wardly.  Thus  it  hangs suspended in  the  solution,
and presents  its two opposite surfaces  to  the  action
of the liquid, and  to  the inner and  outer cylinders
of copper respectively.  There  is a  screw-cup, N,
connected  with  the zinc  cylinder,  and also  one
marked P,  with the copper cylinder; and, according
to the principles heretofore explained,  when a com-
munication is made between  these  cups, the elec-
tricity developed by the action within the  battery
will pass from  one  to  the other.
        Fig. 12.           Fig.  12 is a perspective
                        view of  the  same  battery,
                        in  which the  parts will be
                        understood  without further
                        explanation.
                          30.  The liquid employed
                        to put this battery in  action
                        is  a solution of sulphate of
                        copper  (common blue  vit-
                        riol) in water.   To prepare
                        it, a saturated solution of the
salt is  first made, and to this solution  is then added
as much more water.   It may be convenient to  know,
that a pint of water, at the ordinary temperature  of
 
    SULPHATE  OF  COPPER  BATTERIES. 21

the atmosphere, is capable of dissolving one fourth of a
pound of blue vitriol;  so that the half-saturated solu-
tion employed  will contain about 2 oz. of the salt
to the pint.   The addition of a small portion of al-
cohol to this solution  is sometimes of advantage, by
increasing  the permanence of its action.
   31.  The action in  this case is as follows:   The
zinc  is  oxidized  by the oxygen of the water; the
oxide  combines with the acid of the salt, forming
sulphate of zinc,  which remains  in  solution; while
the oxide of copper, which was previously combined
with  the acid, being set free, partly  adheres to the
surface of the zinc cylinder, or falls to the bottom of
the solution as a black powder, and partly is reduced
to metallic copper, which is precipitated  on the sur-
face of the  copper cylinder, or falls to the bottom in
fine grains.   This reduction of the oxide to the me-
tallic  state takes place in the following manner: The
water  of the solution  furnishes oxygen  to  the  zinc,
and thus enables it to  combine with the acid; while
the hydrogen, which is  liberated, again  forms water
with the oxygen of the  oxide of copper with which
it  comes in contact, leaving the metal free.  Hence
but little gas is given  off during the  action  of a
battery charged  by sulphate of copper, as  the hy-
drogen, which  usually escapes, is in this case mostly
absorbed.
   ?>2.  In this  form of battery, there  is greater in-
tensity  in proportion to the  quantity of  electricity
produced than in Smee's, from the  fact that the final
decomposition falls on oxide  of copper, and  not on 
22
DAVIS'S  MANUAL.
water, which  is  separated  into  its elements with
greater difficulty than the former.   The  force of a
galvanic  battery is equal, other conditions being the
same, to  the amount of corrosive force in the solution,
minus the force  of chemical affinity which  has to
be overcome in the decompositions which necessarily
attend the process.   The sulphate  of copper battery is
found more convenient than any other in a large class
of experiments, and also  generally  in the hands of
persons to whom  the  use  of acids  would be  incon-
venient.   The solution of sulphate of copper  is en-
tirely neutral, and does not injure the colors or texture
of organic substances.  Smee's battery is a more con-
densed form, and  the  action on an equal  surface of
zinc more energetic.
   33.  The coating of oxide of copper should always
be removed from the zinc after  using  the battery.
For this  purpose a card brush is provided.  With this
the surface of the zinc should be thoroughly cleansed,
with the aid of plenty of water, whenever it has been
in use.   If this has been neglected, so that the zinc
has become covered, in whole or in  part, with  a hard
coating,  it will be necessary to  scrape  or file it, to
obtain a  clean  metallic surface.  The deposit of cop-
per, also, which  will  gradually accumulate  below,
must  be  removed from time to time.
   34.  Batteries excited  by  sulphate of copper  will
keep in good action  for twenty or  thirty minutes  at a
time.   The zinc cylinder should always be taken out
of the solution when the  battery is not in use, but the
solution itself may remain in the battery, as it has no 
PROTECTED  BATTERIES.        23
 chemical action upon the copper, but tends to keep
 its surface  in  good  condition.   When  the solution
 has lost its power,  as- it will do,  of course, after a
 time, it is not best to attempt to renew  its efficiency
 by adding a fresh quantity of the salt.   It should be
 thrown away,  and  a new solution be prepared,  ac-
 cording to  the foregoing directions.
   35.  Fig. 13 represents a Protected Sulphate of
 Copper Battery. — It has  been stated,  in § 31, that
                 the zinc soon  becomes coated with
                 oxide of copper or pulverulent me-
                 tallic copper, and the action of  the
                 battery consequently declines. Now,
                 the efficiency of sulphate of copper
                 in   providing  oxide of  copper  to
                 undergo decomposition in place  of
                 water,  is equally great  in the final
                 result when  it forms only that part
                 of the solution next the copper plate.
                 Accordingly,  by interposing  a cell
 of porous earthen ware between the zinc and cop-
 per, two cells are produced, in the outer one of which
 sulphate of copper may be used, and in the inner one
 a solution of Glauber's salt (sulphate of soda), or com-
' mon salt.   These do not coat  the zinc, though suf-
 ficient  of  the  copper  solution will eventually pass
 through to  make it necessary  occasionally to  clean
 the zinc  plate.   Dilute sulphuric  acid  may also be
 used in the inner cell;  but in this case, it is necessary
 or advisable to amalgamate the zinc.  A lip will be
 observed in the  figure, which is used: for adding:
 
24
DAVIS'S  MANUAL.
  36.  Fig.
this form.
    Fig. 14.
crystals of sulphate of copper to the solution as its
strength declines.
            14  shows  the internal  construction of
           In  the centre is seen a solid rod of zinc,
                 with the space for the  saline or acid
                 solution surrounding it.  Next comes
                 the  porous cell;  and  without this
          p   /  again  the space containing the sul-
            (    phate  of copper solution.   It is ne-
                 cessary,  after  the  porous cell  has
                 been in use, to allow  it to soak in
                 several waters before drying it to put
               - jaway.   Otherwise  the salts which
                 are contained in it  will crystallize in
the interstices and disintegrate its substance.
   Fi<r. 15.       37.  Another  form  of protected sul-
             phate of copper battery is represented
             in  Fig.  15, the chief  difference  con-
             sisting in  the porous  cell, which is of
             thick leather.  Except, however, where
             batteries  of a  particular shape  or size
             are required, for  which earthen ware
             cells cannot readily be obtained,  those
previously described are  preferred.
    Fig. 16.       38.  Fig. 16 represents a protected '
              battery,  in  which the leather forms a
              double cell, enclosing the zinc, so that
              a  double  cylinder  of copper  can be
              used, as in the cylinder  battery (Fig.
               11), and both  surfaces of the zinc are
thus  opposed to corresponding  surfaces  of  copper.
 
PROTECTED  BATTERIES.        25
Other  porous  or  membranous substances,  such  as
thick brown paper, or bladder, will answer the same
purpose as leather, in preventing the ready admixture
of the solutions, and allowing a  free passage to the
electrical current.   When the partition is sufficiently
thin or permeable, the  battery is as powerful as if
charged in  the usual mode with  a solution  of blue
vitriol.
  39.  The  action within this class of batteries is as
follows :  The zinc is oxidized as usual, at the expense
of the water of  the solution which surrounds it ;
while the hydrogen, instead of being given off at the
surface of the negative plate, as in most batteries,
decomposes  the sulphate of  copper, forming water
with the  oxygen of the oxide of copper,  and liber-
ating  the  sulphuric  acid, which passes through  the
porous partition into  the other cell.  A gradual and
steady supply of acid is  thus furnished to dissolve
the constantly forming oxide of  zinc.
  10.  The  protected battery is also commonly called
constant, or sustaining, from the fact that it will main-
tain a nearly  unvarying  power for  several days in
succession,  if the solution  of sulphate  of copper is
kept saturated by occasionally adding a little of the
pulverized salt and stirring the liquid, to make it  of
uniform strength.   With weaker  solutions, or a  less
permeable partition, an action of sufficient energy for
many purposes may be sustained for a week or more,
and, when it  declines, may be renewed by cleaning
the  zinc plate, and removing any loose deposit from
the  cells.  This constancy of action  renders the bat-
              3 
26            DAVIS'S  MANUAL.

tery of great value in the electrotype process, which
will be described hereafter.   The deposition of me-
tallic  copper on the negative plate  is the  principal
inconvenience attending it:  this deposit sometimes
adheres so firmly as to be difficult of removal, which,
however,  is only  necessary  when  it  interferes me-
chanically  with the working of the battery.
  41.  Grove's  Battery.—The sulphate of copper
batteries, which have been spoken of, have been some-
times  called  hydrogen-consuming batteries,  because
they provide a chemical agent, oxide of  copper, with
which the  hydrogen produced in the first instance by
the decomposition of water, unites to form water
again, thus separating copper from its oxide in the
metallic  form.  The only  chemical  affinity which
has to be overcome, in this battery, is that of oxygen
for copper.  Its force may be  stated as  equal  to the
affinity of oxygen for zinc, minus the affinity of oxy-
gen for copper.  In Grove's battery, which is now
to  be described,  a further  advance is  made.  The
electro-negative metal,  as   in  Smee's,  is  platinum,
which, from the condensed  form of the battery, can
be used without too great expense.  Instead of sul-
 phate of copper,  strong nitric acid is employed for
 the purpose of furnishing oxygen  to the  hydrogen,
 with the following advantage:  Nitric  acid  consists
 of five equivalents of  oxygen and one of nitrogen.
 The fifth equivalent of oxygen is held  by a  very
 slight affinity, many  chemical agents  sufficing  to
 reduce the nitric  acid to nitrous acid, which has  one
 equivalent less.   The  increase of power in Grove's 
grove's  battery.
27
battery over the  sulphate of copper battery, for  the
same amount of zinc dissolved, is equal to the differ-
ence of affinity between oxygen for nitrous acid and
oxygen for copper.  The force of Grove's battery is,
therefore,  equal to  the affinity of  oxygen for zinc,
minus the  affinity  of oxygen for nitrous  acid.
  42. It should also be remembered that the energy
of a galvanic arrangement  depends, to some extent,
upon the difference  in the  affinity for oxygen of the
metals employed, which,  in the case of platinum and
zinc, is at a maximum.  The zinc plates  are  amal-
gamated, and  the battery  is worked by two  fluids;
the one within the porous cell and in contact with
the platinum being strong  nitric acid, and  the other,
which is in contact with  the zinc, being  sulphuric
acid, diluted with ten or twelve parts of water,  as in
Smee's, $  25.    This battery is the most energetic
yet known.  A Grove's battery,  exposing  a surface
of zinc equal to 20 square  inches, was found,  by its
magnetizing  power, to  afford a current of greater
quantity  than a sulphate of copper battery  exposing
210 inches of zinc.   The  intensity  of the current in
Grove's is also considered  three times as great as in
the latter, and perhaps four times as great as in Smee's.
The same  platinum and zinc of a Grove's battery,
being used as a Smee's, gave less than a fifth of the
current in  magnetizing  power.   Grove's battery is
also exceedingly constant.
  43. The disadvantages of this  battery for common
use are, first, the strength of the acids which are  em-
ployed, making it disagreeable and unsafe to a careless 
28              DAVIS'S  MANUAL.

experimenter ; and, secondly, the red fumes of nitrous
acid which  it gives off abundantly while  in action.
These are irrespirable and injurious to nice apparatus
which may be exposed to them.   By placing a me-
tallic covering (protected  from the acid  fumes) over
the battery, and allowing the gases to escape through
an  orifice stuffed  with cotton, wet  with a little  al-
cohol, these may be, to some extent, neutralized.  It
should  also  be remarked that the  quantity of  elec-
tricity produced is, in  all these batteries, proportional
to the quantity of zinc  dissolved; and where a small
surface of zinc gives a  large current, it is acted upon
with greater  rapidity.   The intensity of the current
produced in these forms depends upon the chemical
affinities which are concerned; and on this account
there is a gain in  the sulphate of  copper battery over
Smee's,  and a still greater in Grove's.
  44.  The construction of Grove's Battery is shown
in Fig. 17.   The containing vessel  is glass.  With-
  Fig. 17.   m  tn*s  *s a  thick  cylinder  of  amal-
             gamated  zinc,  standing on  short  legs,
             and  divided  by a longitudinal opening
             on one side, in order to allow the acid
             to  circulate freely.  Inside  of this is a
             porous cell  of unglazed porcelain, con-
             taining the nitric  acid and strip of plat-
inum.  The platinum is supported by a strip of brass,
fixed,  by a thumb-screw and an  insulating piece of
ivory, to the arm  proceeding from the zinc cylinder.
The  amalgamated zinc  is not acted upon by the
dilute sulphuric acid until the circuit of the battery
 
grove's  battery.            29
is  completed; but  a small portion of the nitric acid
filters  through the  porous cell, by which the zinc
would be readily attacked.  It is therefore advisable
to  remove it from the  acid when the battery  is out
of action for any length  of time.
   45.  Fig.  18  represents  a  series  of  twelve  pairs
of Grove's Battery.   In this compound battery,  each
                       Fig. 18.
strip of platinum, except the terminal one, is soldered
directly to the arm projecting from the  adjoining zinc
plate.   The terminal strip,  with its  screw-cup, is
supported by the first zinc plate, but  is  insulated from
it, as in Fig. 17.   Such a series is of  very consider-
able practical importance, as it  is now extensively
used for purposes requiring  a constant galvanic cur-
rent of great quantity and intensity.   It is the form
which is in almost all cases resorted to for the mag-
netic  telegraph.   For chemical  and illustrative  ex-
periments requiring a current of great power, this has
now,  to a considerable  extent,  superseded the older
form of consecutive  plates,  which will be described
immediately.   It was  stated  that  Grove's  battery
may be considered as having three times the  inten-
              3* 
30
DAVIS'S  MANUAL.
sity of the sulphate of copper battery.   A  series of
twelve  pairs,  therefore, would  be as  powerful  as
thirty-six pairs of the latter ; and  more so  than  the
same  number  of pairs in which only sulphuric acid
is  employed.
   46.  In Fig. 19, the Trough Battery, hitherto so
much used, is represented.   In the form in  which it
is  shown,  the plates can  be suddenly  immersed or
withdrawn  from the acid at pleasure  by means  of
the windlass.  The zinc plates are flat, and inclosed
                              in copper cases, open
                              at  top   and bottom.
                              There is no division
                              of the acid into sepa-
                              rate cells.   A  repre-
                              sents the  trough, B
                              the wooden  case con-
                              taining   the  plates.
The liquid used  is sulphuric acid,  diluted with forty
or fifty parts of water.  If greater power is desired.
a  little  nitric acid  may be added.  E E are small
hand-vices, connected with the poles, for the purpose
of holding wires, &c.  The battery represented in the
cut,  consisting of twenty-five  pairs of plates,  should
be able to ignite a considerable  length of wire, to
decompose  acidulated water with rapidity, and  to
give a brilliant  light with charcoal points.
   47.  Fig.  20 represents  a larger battery of a sim-
ilar construction.   There  are  two  distinct  series  of
fifty pairs, each  connected with two of  the  four cups
on the table  above  the  battery.  In  this  way  the
 
TROUGH  BATTERY.
31
whole may be used as a single  series of one hundred
pairs, or as a battery of fifty pairs of double size, by
establishing proper  connections between these cups.
Or only half the battery may be  put in action, each
having a separate trough  to contain the acid.  The
plates are stationary, and the troughs are raised up  to
them by means of two racks moved  by the crank
and  handle, H, which lift the platform on which the
                     Fig. 20.
troughs stand.  Either trough may be removed from
the platform at pleasure, when it is wished  to  use
only half of the  battery.
  48.  In the cut, the arrangement for producing the
arch of flame between charcoal points is shown.  Two
pointed pieces of prepared boxwood charcoal are fixed
in the  pincers  at A, and, the battery being put  in
action,  are  brought  in  contact.   The spark passes,
and the points  become  ignited.  They may then be 
32             DAVIS'S  MANUAL.

separated  to a greater  or  less distance, in  proportion
to the power of the battery ;  and the  current  will
continue to flow through the interval with  the  pro-
duction of intense light and heat.   This experiment,
as well  as  the deflagration or destructive combustion
of metals,  is performed with  facility by a series of
Grove's battery.
   49.  In the batteries just  described, in  which the
plates are fixed permanently in a frame, the solution
of sulphate of copper cannot be employed, on account
of the deposit  which  it forms.  Hence diluted  acid
is used; and the batteries will not maintain a good
action for more than  a few  minutes at a time; in
fact, their  highest rate of action  only continues for a
few seconds  after  immersion.  The plates require to
be taken out of the acid  occasionally during the ex-
periments, and  exposed to the air a minute or two.
   50.  Physiological  Effects  of  Galvanism. —
The nervous system of animals is very  susceptible
to the galvanic  influence ; so much so, that the sensa-
tions and motions, thus excited, are among  the most
 Fis 21  delicate tests  of the existence of  a galvanic
f  current.  It was by observing the contrac-
       K tions in the leg of a frog, when two dissimi-
         lar  metals, happening to rest upon it, were
         brought in  contact  with each other,  that
         Galvani laid  the foundation of the science
       t  which bears  his name.   This  primitive ex-
       V periment is shown  by the apparatus repre-
sented in Fig. 21, where  a strip of silver and one of
zinc are attached  to a little block of wood  or ivory. 
PHYSIOLOGICAL  EFFECTS.       33
One of the  metals  is  curved over above, so  that it
may be brought in  contact with the other by a very
slight pressure of the finger.   The lower extremities
of the metals approach,  and are made to grasp the
thigh of a grasshopper recently killed.  On making
contact between  the metals above, the limb will be
extended, and on removing the finger, it will again
contract.  In  this  case, as  in the frog, the exciting
fluid of the galvanic pair is the moisture  of the skin
or the natural  fluids of the animal, where the skin
is removed.
   51.  The same  apparatus, of larger  size,  serves
to show  the contractions  produced in the leg of a
frog.   In this case, a  great amount of motion  is pro-
duced by an almost insensible current; and the only
objection to the experiment is, the destruction  of life
which it requires,  and the difficulty  of  always ob-
taining the animal.   The legs are prepared,  as in
                      Fig. 22.
Fig. 22, by removing a small portion of the lumbar ver-
tebra?, with  the extremities attached, from a subject 
34
DAVIS'S  MANUAL.
recently killed, and stripping off the skin.  The legs
are shown  in  the figure  in a contracted  position,
in which  they are placed before completing the cir-
cuit.  The dotted lines exhibit the extended position
which they assume under the influence of the current
   52. Many animals residing  in the  water are  very
sensitive to  the galvanic current, owing partly, with-
           out  doubt, to the large  surface  they ex-
           pose to the  conducting  medium, water.
           Fig. 23 represents a similar galvanic pair
           to that described  above, introduced into a
           glass vessel containing a leech;  one metal
           being  on  each side of  the animal.   On
           completing contact, the leech is instantly
           disturbed, and  endeavors to  escape from
           its position in the  course  of the  current.
           A small fish,  in  a similar position,  also
           exhibits sensibility; and where a  stronger
           current is passed through the water, as will
           be mentioned under the head of " Animal
Electricity," the creature exposed to it becomes rigid
and  incapable  of motion.   A powerful current in-
stantly deprives it of life.
   53. If a leech, or fish-worm, be placed on a disc of
silver, such as a silver dollar, (Fig. 24,) which rests on
   ,,. r ni     a moistened plate of zinc, the animal will
             show no uneasiness  while it remains on
             one metal, but will  instantly withdraw
             on attempting  to pass  the limit which
             separates one plate from the other, with
all the appearance of  receiving  a  painful  electrical
discharge.
 
CONDUCTION  OF  GALVANISM.
  54.  The earliest of  all observations in galvanism
was undoubtedly the sensation  produced by dissimi-
lar metals, when placed above and below the tongue.
If the edges of a piece of silver  and zinc, so situated,
are  brought  together, a  metallic  taste and stinging
sensation  are instantly perceived, the tongue being
placed, with reference to the metals, just as the leg of
the grasshopper or frog, in  Figs. 21 and 22.  If one
of the metals be placed under the upper lip,  instead
of on the  tongue, the eye will apparently see a flash
of light when they are brought together.
  55.  Conduction  of   Galvanism.—Metals differ
very  much in  their power of conducting galvanic
electricity.   The  following appears to be  the order
of conducting power in a few of the most  useful
metals — silver, copper, brass,  iron, platinum ; the first
named being the  best  conductor.   For conducting
wires or  poles, copper is  generally used ; for delicate
connections,  silver.  The difficulty of conduction of
course increases with the length  of a metallic wire, and
this becomes an important consideration in the con-
struction of galvanic apparatus.  The wires  employed
with batteries should always be  of sufficient size, and
of pure and  well-annealed  metal.  It will  be found
that they lose  much in conducting power  by being
frequently bent.
  56.  Iron and  platinum are  used  where it is an
object  to  employ the poorest conductors,  as in ig-
niting a wire.  Galvanic ignition seems to result from
a law, that, in proportion to  the  resistance made by
the  substance of a conductor  to the passage of elec- 
36
DAVIS'S  MANUAL.
tricity, heat  is evolved.  Thus, when  a current of
electricity is passed through a metallic wire in greater
quantity than it  can readily transmit,  the  wire be-
comes more or less heated.   If its length and thick-
ness be proportioned to the power of the battery, it
may readily be melted.   A single pair of plates would
be the most  suitable arrangement  for producing this
effect, were  it not that an  increase of  intensity en-
ables a greater quantity of electricity to traverse the
wire.  Hence, for igniting  a great length of wire, a
battery of a considerable number of pairs  is neces-
sary ; but a much thicker wire may be ignited  by a
few  pairs  of large  size.   When a very extensive
series of small plates is used, the current acquires so
high an intensity that its powder of producing ignition
is diminished, as it  becomes capable of traversing a
pretty fine  wire  without obstruction.
  57.  Either of the batteries of single  pairs, which
have  been described, have  sufficient power to ignite
a fine wire of iron, or other metal, through which the
current is  made to  pass.  This effect is most easily
produced in  those  metals  which offer  the  greatest
resistance,  not only to  the  passage of electricity, but
also to that of heat; hence a larger wire of platinum
may be ignited than of perhaps any other metal, as
it  is  a  poor conductor both of  electricity  and of
heat.   A steel wire, when  intensely heated in this
way, burns with beautiful scintillations.   The shorter
and  finer the wire, within certain limits, the greater
is the effect produced.
  58.  Fig. 25 represents an  instrument, by means 
        CONDUCTION  OF  GALVANISM.     37

of which the current may be made to  pass through
various  lengths  of wire.   The sliding  arms may be
            Fig. 25.             fixed in a variety of
                               positions,   so  that
                               their    extremities,
                               holding  the  wire.
                               may be at different
                               distances  apart.  A
                               fine wire, if not too
                               long, thus interposed
                               in  the  course  of  a
                               powerful current, is
                               immediately   fused
or  deflagrated.  This instrument  has  been used to
determine the conducting  power of metals,  by pas-
sing the current of  a constant  battery through an
instrument  capable of  measuring  its  magnetizing
power,  and then also opening a collateral circuit to
the  same current through a certain  length  of fine
wire, first of one metal, then of another.  The in-
strument employed to measure the  magnetizing pow-
er  was the Magnetometer,  which  will be described
hereafter.  In this instance, the current is divided:
a portion of it, equivalent to the  conducting power
of the  metal under  experiment, passes through the
fine wire;  and the  measuring instrument,  through
which the remainder of the current passes, indicates
a corresponding diminution.   When the whole cur-
rent was made  to  pass through  the  instrument, the
magnetizing power in one experiment was  24,400
grs.; that  is, the electro-magnet employed attracted
              4
 
38
D A VIS ' S  MANUAL.
its armature with  a force equivalent to this weight.
The following table will show the  reduction of this
amount, when fine wires of various  metals were em-
ployed in the way above  described.
Magnetizing Power.   Reduction.
Silver coin,	7,350	grs.	17,050	grs.
Copper,	8,180	u	16,220	u
Pure silver,	8,800	a	15,600	u
Brass, .	12,046	ic	12,354	a
Gold coin,	12,820	ct	11,580	a
Iron, . .	16,600	u	7,800	u
Platinum, .	17,010	n	7,390	u
  The conducting power of the  metals  is, of course,
in proportion  to  their reduction of the  magnetizing
power of the collateral  current.  The alloy of silver
with a little copper used in coinage, is the best con-
ductor of the rnetals tried, and platinum the poorest.
  59.  Powder  Cup.   In  fig. 26  is represented a
little instrument designed to show the heating power
of the battery current.   Two copper wires, wound
with  cotton  thread, except at  their ends, are  joined
by a short piece of fine platinum wire.   These wires
pass through the bottom of a  small glass cup, C, so
that the platinum  wire lies free  in its cavity.  On 
            VOLTAIC  GAS  PISTOL.         39

putting a little gunpowder  into the cup, C, and then
connecting  the copper  wires  with the poles of the
battery,  the  platinum will  become heated, in conse-
quence of the flow of the current through it,  so as to
inflame  the powder.  The recent discovery  of gun-
cotton has a  very useful  application  to this  instru-
ment,  and  to the galvanic battery generally, as  a
means of igniting explosive compounds.  The tem-
perature   at which  gun-cotton explodes being only
about  360° F., requires a  comparatively  slight  ele-
vation of temperature in  the wire.   For  blasting
or submarine explosions, this  will be an important
advantage.
   60.  The Voltaic Gas Pistol, represented in Fig.
27, is  constructed on the same principle as the last-
described instrument.   The wires pass up through a
brass piece which screws into the barrel, they being
completely insulated from  each other.  A sectional
              Fig.  27.             view  of this part
                                 is annexed.  The
                                 fine  platinum wire
                                 stretches across be-
                                 tween  the  two.
                                 The   introduction
                                 of a  proper quan-
                                 tity  of  hydrogen
                                 gas may be effected
in the following manner: Connect with a self-regula-
ting reservoir of hydrogen a leaden or other tube, so
bent as to deliver the gas under the surface of water
in a jar.   The pistol being uncorked, and the brass

 
40
D AVI S ' S  MANU AL.
piece  unscrewed, immerse  the  muzzle  in the jar to
such a depth that the water  may  fill one quarter of
the barrel.   Then replace the brass piece, and, bring-
ing the muzzle over the end of the tube,  open the
stop-cock  of the  reservoir.  When  the escape  of
bubbles shows  the pistol to be full of gas, withdraw
it, and insert the cork.  In  this way it will contain
one volume of  hydrogen  to three of  air,  which is
the best proportion.   If too much  hydrogen is intro-
duced, no explosion will occur.   It is  not,  however,
necessary to be very particular ;  and it will  answer
the purpose almost equally  well, without  going
through the troublesome process above, if the pistol
is held for a few moments over a jet of the  gas.
The explosion is louder and more certain  to occur,
if it  is  filled  with a mixture of oxygen and  hy-
drogen, in the  proportion of one  volume of the  for-
mer to two of the  latter.
   61.  The pistol being corked, connect one of the
wires with the  zinc  pole of the battery, and the other
with  the copper pole.  The  circuit will now be com-
pleted through the platinum  wire; this will instantly
be ignited,  setting fire  to the  gas, which will expel
the cork  with a loud report.   The removal of the
brass piece  and wires  allows the  mixed gases to be
fired  by the application of  flame  when desired.
   62.  Galvano-Decomposition. — It has been stat-
ed, that the liquid between the  plates of the  bat-
tery  undergoes  decomposition as a  condition  of
the passage  of the galvanic current.   It  was  also
stated that  this took place not only in the battery, 
GALVANO-DECOMPOSITION.       41
but whenever the current produced by it was made
to pass through a liquid consisting of  more than one
element.  In this case, it is found that a certain class
of substances always appear at one pole of the  bat-
tery,  and a certain class  always at the other pole.
Thus, when solutions  of metallic  or  other  salts are
decomposed, the metal, or base, always appears  at
the zinc, or negative pole; while the electro-negative
element, previously in combination with the metal  or
base, as chlorine, oxygen, cyanogen,  appears  at the
other, or positive pole.   The decomposition is exactly-
proportional to the quantity of electricity which passes;
and  instruments have  been  contrived  to measure
the  current, by measuring the  amount of matter de-
composed by  it.   It is also found that, for a given
amount  of electricity, a definite proportion of  each
element  is evolved;  and  these proportions are the
same as the chemical  equivalents of  those  elements.
 Substances  differ  very  much  in  the  facility  with
 which they are decomposed.   Some form  the  most
 delicate tests we possess of the passage of  an electric
 current.   Others require the most  powerful galvanic
 apparatus to separate  them into their elements.
   63.  If the poles of  a battery of  two or three pairs
 are made to terminate in strips of platinum, and  to
 dip  into water, a  slender stream of gas will be seen
 to arise from each wire, hydrogen being evolved from
 one, oxygen from  the  other.   If the wires  are of iron
 or copper, the oxygen will unite with the one con-
 nected with the positive pole to form oxide of iron
 or of copper, and hydrogen alone will be  given  off.
               4* 
42
DAVIS'S  MANUAL.
Platinum wires or strips are not attacked by the oxy-
gen, and are therefore best for the decomposing sur-
faces.  The  decomposition of water is greatly facili-
tated by dissolving  in it some salt, as, for instance.
Glauber's salt, or, what  Is  still  more  effectual, by
the addition of one part of sulphuric acid to ten or
fifteen of the water.  These substances increase its
conducting  power.  If, however, the power of con-
duction  be  increased beyond  a  certain  limit, the
evolution of gas  will be  lessened.
   64.  Fig.   28  represents  a  Decomposing  Cell,
mounted  on  a stand.   Two  platinum wires, con-
                    nected with the cups A and B on
                    the stand, pass up  into the cell,
                    which is of glass.   A glass tube,
                    G,  may  be inverted  over  these
                    wires, to collect any  gas  which
                    is evolved;  it  passes  through  a
                    cork, fitting the mouth of the cell
                    with sufficient tightness  to allow
                    the  tube  to  be filled with the
                    liquid by merely   inverting the
                    instrument.   The cell,  being part-
                    ly  filled with  acidulated  water,
                    and  the  tube, wholly full, con-
                    nect  the cups,  A  and  B, with
                    those  of the  battery.   Immedi-
                    ately bubbles of gas will be seen
                   to escape from each wire, and to
                   rise into  the  tube, displacing the
liquid from it.  When the tube is full,  it may be re-
 
GALVANO-DECOMPOSITION.      43
moved and the mixed  gases  exploded by  holding
its mouth  to  a flame.
  65.  By  having  two glass tubes, O and  H, passed
through a cork, so that one of  them may be  inverted
over each wire, as shown in the cut, where p p are the
platinum wires, the gases may be obtained separately ;
oxygen only  being collected in the tube placed over
the positive wire,  and  hydrogen  alone in the other.
The volume of the latter gas is twice that of the for-
mer, as indicated in the  figure  by  the relative height
of the liquid in the tubes O and H, occupied respec-
tively by the oxygen and hydrogen.   On removing
the tubes  when full, the hydrogen will  burn if a
flame  be  applied,  and the  oxygen will increase the
brilliancy of the combustion of any ignited body put
into it.  When these tubes  are graduated, they con-
stitute the instrument  called  voltascope, or voltam-
eter.    The   amount  of gas  liberated is  exactly
proportioned  to the electricity  which passes,  and
affords the most exact  measure of the amount of a
current when it continues for any length of  time.
   66. A solution of iodide of potassium  is perhaps
more easily decomposed than any other salt.   In this
case, instead  of the  elements  of water, the compo-
nents of the  salt itself appear  at the poles;  iodine at
one side, and  potash,  by a reaction between potassium
and water, at the other.   When iodine and starch
are  brought  together,  an  intensely  blue precipitate
results.  Melloni availed himself of this fact,  to deter-
mine the heat of insects, in some of the most delicate
experiments  ever  made,  by means of his  thermo- 
44            DAVIS'S  MANUAL.

electric pile.  A  little  starch  being  added  to  the
solution of  iodide of  potassium,  the passage of the
slightest  electrical current is made apparent  by the
blue precipitate at the positive  pole.   The direction,
as well as the existence, of a current is thus  shown.
The decomposing cell  (Fig. 28) will answer for this
experiment;  but a more delicate  form  is shown in
Fig. 29,  where a glass tube  is  supported on  a stand,
     „.  „      two platinum  wires, each connected
     Fig. 29.          r
                with a small screw-cup, entering on
                opposite sides.   These wires are in-
                sulated,  except  at the extremities,
                which are flattened  into little discs,
                and are parallel to each other.  When
                a  current  of  almost  inappreciable
                quantity passes, as  that from a gal-
                vanic  pair composed of a zinc and a
silver  wire, whose  extremities are  dipped into  dis-
tilled  water, or from  two or three  turns  of  a small
electrical  machine,  one of these  discs will  be  seen.
when  compared in  the light with the other, to be-
come of a purple hue, the effect constantly increasing
as the current  is continued.   The  disc recovers its
brightness by stirring the solution  near it, or  on being
touched  with a  little splintei  of  wood.
   67.  Most of  the salts having  alkaline bases are
decomposed into an acid and an alkali, which appear
at the opposite poles.   Some  of the  phenomena
occasioned  in this way are best observed  by placing
a porous  diaphragm across  the decomposing cell, so
as to form  separate apartments for the poles.   Fig.
 
GALVANO— DECOMPOSITION.      45
30 represents a tumbler divided vertically; with the
edges ground together,  so  as  to form a tight joint,
      Fig. 30.       when they include between them
                   a diaphragm  of unsized  paper.
                   They are  held  together by rings
                   of India rubber.  A little screw-
                   cup  is  clamped to  the  side  of
                   each of  these  apartments,  from
                   which   platinum   poles  descend
                   into  the vessel.
                    68.  Let this apparatus be filled
with a solution of Glauber's salt, (sulphate of soda,) to
which has been added enough of the  infusion of red
cabbage to give it a blue  color.   On the passage of the
current from a single pair, the blue color will soon be
changed to red in the cell containing the positive pole,
and to green in  the other, sulphuric acid and soda
being respectively evolved.  By reversing the current,
the original color will be first restored in each cell, and
then the opposite change will occur.   If the solution
is colored blue by the infusion or  tincture of litmus,
it will become red in the  cell  in which the acid is
developed, but will suffer  no change  in  the other.
When the yellow infusion  of turmeric  is used, it is
turned brown by the alkali evolved in the negative
cell,  but  is not affected by the acid  in  the other.
Similar phenomena present themselves with  a large
number of salts,  but in some cases different effects
are produced.
  69.  If  a  solution of muriate of ammonia, colored
by some  vegetable  infusion, be employed,  chlorine
 
 46            DAVIS'S  MANUAL.

 gas will be given  off from  the  positive pole.   This
 may be recognized by its peculiar odor, and by the
 bleaching effect  it produces  upon the  liquid in the
 positive cell,  which  quickly becomes colorless.  In
 this case,  ammonia and  hydrogen are set free in the
 negative cell, and  muriatic acid  and oxygen should
 have  been  liberated  in the  other.   The  chlorine
 appears therefore to be a secondary product, set free
 by the combination of the hydrogen of the muriatic
 acid with oxygen,  to  form water.  Or, according to
 the view which regards sal-ammoniac as a chloride of
 ammonium, chlorine is directly liberated at the  posi-
 tive  pole;  and at  the negative,  ammonium, which,
 not  being able to exist  in  an isolated  state, is in-
 stantly  resolved  into  its components,  ammonia and
 hydrogen.
   70.  In most cases, it is desirable  to  have  the dis-
 tance between the poles in  the  decomposing cell  as
 small as possible, as the current passes more easily
 and  the action  is more  rapid.   Where,  however,
different colors are  to be exhibited, the instrument
                         represented in Fig.  31  may
                         be  used with advantage.
                         This is a U-shaped tube, in-
                        to which the poles  enter at
                        the top.   It may either  form
                        a continuous cell,  or it  may
                        be  divided  by thrusting a
                        piece of loosely crumpled,
                        unsized  paper, or of cotton
                        cloth, into the bend ; or the
 
           ELECTRO — METALLURGY.        47

tube may  be in two  parts, cemented together into
a brass support or stand, with a porous diaphragm be-
tween.   When the experiment with sulphate of soda,
$68, is tried  with this instrument,  three separate
zones of'color, blending into each other, are  perceived.
At the positive  pole, it is red ; at the negative, green ;
and  in  the region between, the color  remains blue.
As the  experiment proceeds, the red and green solu-
tions encroach on  the blue, until a small space only
remains  between them,  if the  tube  is  continuous,
where the  acid and alkaline portions blend  together.
  71.  Electro-Metallurgy. — Solutions  of  metal-
lic salts undergo decomposition in the same way as
the  alkaline salts.  The result is the deposition of
the metal itself at the  negative pole.   Even with the
alkalies, a battery of great power, in place of the alka-
line  oxide usually evolved,  separates the metal which
is its ultimate  base.   The  decomposition in alkaline
and  metallic salts  takes place, probably, in the base
of the salt, the  metal being  separated at one side, and
the oxygen, or  electro-negative element, at  the other.
In some cases, as with the alkalies, the elements thus
eliminated  decompose water, and an  acid  and alkali
finally appear at the poles.  The deposition of metal
has been spoken of in the sulphate of copper battery.
The observation of this important fact,  in its connec-
tion  with  the  mechanic arts,  was made  at about
the same time, in 1837  and 1838, by Jacobi,  of  St.
Petersburg, and Spencer, of Liverpool.   The science
of The  Electrotype, or Electro-metallurgy, thus had its
origin. 
48            davis's  MANUAL.
   72.  The  great  object  in depositing  metals is to
 throw them down in a malleable, coherent state — the
 reguline  condition.  If different  metallic  solutions
 should be put in one of the decomposing cells already
 described, it will be found that copper will probably
 be deposited on one of the poles with its proper color,
 while  silver  and  gold  will be thrown down as a
 black powder.   A great difference, therefore, exists
 with the different  metals.   Some  practical directions
 will be given  for  the  precipitation of those  most
 important.
   73.  Metals  tend to be thrown  down  in three dif-
 ferent states — as a  black deposit, as reguline metal,
 and in a crystalline  condition.   These forms all de-
 pend upon the  fact, that  in the  decomposing  cell
 there are two bodies present, water and the metallic
 salt, either or both of which may be decomposed by
 the  galvanic current.  Now, when water  is  decom-
 posed, hydrogen is evolved at the  negative pole; and
 when this takes place at the same time that the metal
 is evolved  at  the  positive pole,  the black  deposit
 occurs.   Smee suggests  that the hydrogen and metal
 are both thrown down  together,  and, the mixture
 being incompatible, the metal appears in an infinitely
 divided state.  As  an illustration of this  principle, if
 a  metallic solution is acidulated,  the water  will be
 more easily  decomposed  as the  acid increases its
 conducting power.    There will,  then, be  a greater
 tendency to  the evolution of hydrogen.  Where a
metallic  salt is  difficult of decomposition, acid  is
sometimes, therefore, added; where a black deposit is 
           ELECTRO-METALLURGY.         49

feared,  it is  avoided.   In  Smee's acid battery,  we
have seen hydrogen evolved at the negative plate ; in
the sulphate of copper battery, we have seen copper
deposited on the negative  plate, but  in a hard and
crystalline condition.  Now,  unite  these  by adding
sulphuric acid to  the  sulphate  of copper  solution,
until you arrive at the point when, copper being still
deposited,  hydrogen is just about to appear, and  the
metal will be  precipitated in a soft and malleable
form.   The  crystalline  state  results from the  depo-
sition of the metal  in obedience to its own molecular
attraction.  In the  reguline state, this is modified by
the chemical agency of the  elements of  water.
   74.  The rule  prescribed by  Smee is in  all  cases
to  regulate the  strength of the battery  current  ac-
cording to the strength of the solution.  The follow-
ing formula for controlling the evolution of hydrogen.
and thereby  regulating  the  quality of  the  metal,
is condensed from his  work on electro-metallurgy.
The  tendency to the evolution of hydrogen, and to
a black deposit of  metal, is increased by  any of  the
following  means:   By  increasing  the intensity or
quantity of the battery ;  by increasing the size of the
positive pole ; by decreasing  the size of the negative
or depositing pole ; by approximating the poles; by
increasing the heat of  the solution; by  weakening
the  solution; by making  it acid.   The tendency to
evolution  of hydrogen may be diminished, and that
to  the  crystalline  form  of deposit increased, by any
of  the  following means:  By diminishing the  inten-
sity or  quantity of the  battery; by increasing  the
              5 
50
D AVI S ' S  MANUAL.
negative pole; by  decreasing the  positive pole; by
separating the poles;  by saturating  the solution; by
making it  neutral; by diminishing  its heat.   It will
frequently be  found that one or more of these means
may be employed in a particular operation, while it
will be impossible  to make an  advantageous  appli-
cation  of others.
  75.  The metal  of the electrotype preserves  the
precise  form  of the  negative pole  or mould upon
which it  is deposited.   A finger-mark, or slight  tar-
nish on the mould, is fa^ii*ftrijr-«^ied by the surface
of the metal throyg/^S^n M&fi^Nwith it.   The
chief applicatioiisg>r th» «Wf <ST presfmA are, the re-
production or  naEmufqgJyijDe gi IggQer of Jnedals, dies,
engraved plates! plaster jc^sts^onjameiitEwraised work,
and generally of" a^> designs m^e^fl  or intaglio.
Daguerreotype pictvjye^jrrff Msc^r^jafoduced on  a cop-
per surface by the same  means.  Another important
application  is the coating  of  the  more  oxidizable
metals with films of the noble metals, as  in gilding
and silvering.   If a sheet of copper  should be thrown
down on an object which it was desired to copy, and
then be separated from it, a reverse impression of the
original would be obtained.  To obtain a fac-simile
of  the  original,  it would  be  necessary to use  this
reverse as a mould, and proceed to precipitate metal
upon it,  as in the  first instance.   This  is accord-
ingly one  of the  processes used to obtain  reverses
or  moulds  of objects to be copied.
   76.  For this purpose, a  medal or  engraved plate
is placed itself in  the  solution and copper deposited 
            COPPERPLATES  COPIED.       51

upon it.   The negative wire of the battery should
be connected with the rim of the medal, and in case
of an  engraved  plate, it  may be  soldered  to  the
corners.  The deposit is apt  to adhere very firmly,
sometimes so much so that its removal is impossible.
This may be  avoided by slightly  greasing or oiling
the  mould, and  then brushing it  over with  a little
dry  copper bronze.
   77.   The mould  thus obtained  may have  a wire
soldered to it, and be placed in the solution like the
original one.   In most cases,  it  will  be  considered
safer to take a mould  of a valuable medal or plate in
soft  wax,  or by  some*o*f the other processes to  be
described.         - "'
   78.   An engraving-  printed from  an  electrotype
plate obtained by  this process,  is-given, as a specimen
of the  art, in the  frontispiece to this  Manual,  in
company  with  one  from the original copperplate.
No difference  can - be detected between the impres-
sions,  except that arising  from the greater or less
quantity of ink left in the  work, as  occurs in differ-
ent engravings printed from a single plate.  This is
an important application of the art, as in cases where
a large  number of impressions are required, or where
it  is  desirable to print  from  a plate in different places,
two  or  more plates have been obliged to be  engraved,
while now it is only necessary to engrave one, which
will  not be injured in the slightest degree by  taking
copies  from it, in  one or other of the modes.   Steel
plates  must not  be placed in  the copper solution
without a modification of the process which is given 
52
DAVIS'S  MANUAL.
in <§, 96.  It was found  that the  electrotype plate
used in  the first edition, wore better and  worked
better than  the  original.   This is  due to the great
purity and equality of the deposited copper  and the
hardness which  can  be  obtained  by  regulating the
current  so that there  shall be the slightest tendency
to the  crystalline deposit.
   79.  One of the early processes for obtaining moulds
is that called abroad the clichee process, which con-
sists in stamping the object to be  copied on fusible
alloy just at the moment of  hardening.   This alloy
consists of three  parts of tin, five of lead, and  eight of
bismuth, and melts at about the temperature of boil-
ing  water.   Rose recommends an  alloy of one  part
tin, one  part lead, and two of  bismuth,  which fuses
at about  200° F.   When the  alloy  is melted, it is
skimmed with a card,  and  the medal  or plate, at-
tached  by wax or otherwise to a handle, is suddenly
and  forcibly pressed upon  it.  When of small size,
a mould  may be made,  by  a  few trials, presenting
an accurate reverse of the original.   The frontispiece
to the  first edition was copied in this  way.   A clean
copper  wire, to be used  as the  negative  pole of the
battery,  is heated at  the  end with a little rosin upon
it, sufficiently to melt and solder itself to  the  edge
of the  fusible  mould,  which is then ready for the
solution.  All parts  on  which the metal is not to
be deposited are protected by  a coating of varnish
or wax.
   80.  The  moulds  heretofore  described  have  been
formed  of galvanic   conductors.   Means have  also 
            ELECTRO-METALLURGY.         53

 been found of using moulds of the important class of
 non-conductors, as wax, sealing-wax, and  plaster of
 Paris.  A mould is easily made of a soft composition
 wax by bringing it to an even surface, and then press-
 ing the object to be copied upon it with sufficient force.
 The surface of the original plate  should be slightly
 oiled and brushed with blacklead, to prevent  its ad-
 hesion.   In  this  way,  very perfect  moulds, even
 of large  objects, are  obtained, and it will be found
 the  simplest  and  best  mode of operating in most
 cases.  Medals, copperplates, wood cuts, pages of type,
 may be thus  copied.  The page in which these re-
 marks  occur,  has  been electrotyped by this process,
 and  may  be  compared  with the others,  which  are
 stereotyped.  Parts  of  wood cuts  in  this  volume
 which  it was desirable  to insert in  more than one
 place, have been multiplied in the same way. Melted
 wax may also be  poured on surfaces which are to be
 copied; but this is more troublesome, and less  suc-
 cessful  than the mode already described.
   81.  It is necessary to render the  surface of  the
 wax  mould a conductor of electricity.   This is done
 by  giving  it a coating of good  blacklead,  which
 should  be rubbed  over  its face with  a soft  brush,
 until it acquires a shining black appearance ;  a very
 thin film is sufficient.   A copper wire is then to be
 bent, so  as to  conform  nearly  to  the  edge  of  the
 mould  in its  whole  circumference,  and then to be
 heated in a lamp, and pressed upon the wax, when it
 will  become  imbedded.    Communication  between
the wire and the face of the mould  is to be insured
              5* 
54
DAVIS'S  MANUAL.
 by rubbing a little blacklead on  the  parts around
 the wire.
   82.  The mould, when thus prepared, may be put
 into the solution, care being  taken to  remove air-
 bubbles.   The deposit  commences  upon  the  wire,
 and extends gradually over the blackleaded portions.
 The mould may be employed again, if a new coating
 of blacklead is given to it.   The metallic moulds can
 also be used any number of times, if uninjured.
   83.  Moulds are obtained  from plaster medallions
 by pressing them upon a matrix of soft wax,  after
 their  pores have been saturated with water.   The
 earlier process consisted in  soaking  them  with  hot
 water, and then pouring on  wax and allowing  them
 to cool  before separating  it.    Reverses of plaster
 casts  are obtained by soaking  them  in  hot stearine,
 tallow, or wax, as long as  any bubbles of air escape,
 and then removing  all excess  of  these  substances
 from the surface, and blackleading as before.  There
 is, however,  a serious objection to placing plaster
 casts in a solution, from the  fact, that, if the smallest
 quantity of sulphate  of lime  is dissolved, it affects
 very injuriously the  deposited metal.
   84.  Where  it is not necessary to get a precisely
 accurate  copy of a surface,  it can be made a  good
conductor of electricity by giving it a coat of copper-
 bronze varnish.  Copper  spreads at once  over this
when placed  in the  solution.    Fruit may thus be
easily covered with a metallic crust, preserving its
form and characteristic appearance.
  85. Impressions of seals may be copied by a very 
BATTERIES  EMPLOYED.
55
 simple process.   They are to be covered with a thin
 film of blacklead, rubbed  on with a  soft brush.   If
 this does not adhere readily, the brush may be  very
 slightly moistened with alcohol, care being taken not
 to  roughen the surface of the  seal.  A wire is  then
 melted into  the  sealing-wax, and the  seal placed in
 the solution.  The  operation  is  similar in all re-
 spects to that required for the wax moulds.   The
 original  seal or stamp may be copied by taking an
 impression in soft wax.
   86.  Where the mould  is of copper, a single cell
 has been sometimes made  to  do the work of both
 battery and  depositing apparatus.   The  mould is
 placed on one side of a porous partition in the copper
 solution, and a wire connects it with a piece of zinc
 on  the other side, in a solution of sulphate  of soda.
 The action  in  this case  cannot be nearly  so  well
 controlled as where a  separate battery is used, and
 the deposited metal is not  as  good.
  87.  To copy small objects,  a single  Smee's  bat-
 tery is  sufficient.  Where a large surface  is to be
 deposited on, it  requires the superior energy of the
 sustaining sulphate of copper battery.  The leather
 cell here  has an important application, as it can be
 adapted in shape  to masses of  spelter or commercial
 zinc, which  is the most  economical form  in which
 that metal can be employed in the large  way.
  88.  With  the  copper plate of the  battery is con-
nected a piece of copper  which is to be immersed
with the  mould in an  acidulated solution  of blue
 vitriol, contained in a glass, or well-glazed earthen- 
56             DAVIS'S  MANUAL.

ware vessel, or in a wooden trough.   The piece of
copper and the mould should both be connected with
the battery, and the copper  placed in  the solution,
before the mould is  introduced;  in this way all local
action is prevented, and the deposition  of  copper
commences immediately.   Any air-bubbles  which
adhere to the mould must be dispersed.   The solu-
tion is prepared by adding 2 oz.  of sulphate of copper
and 1 fluid oz. of sulphuric acid to  every 15 fluid
oz.  of water.   As  the copper  is deposited on  the
mould, an equal  quantity  is dissolved off from  the
immersed plate, so that the original strength  of  the
solution  is maintained except for the loss of water by
evaporation.
  89.  Fig. 32 represents a Smee's  battery, B, of the
mercurial, or " odds and ends " form, a new and  im-
            2^v 32.             proved  variety, con-
                               nected with a  depos-
                               iting  apparatus.   A
                               little mercury is plac-
                               ed in  the bottom  of
                               the glass vessel form-
                               ing the battery.   A
                               platinum plate  is seen
                               suspended in the cen-
                               tre, beneath one  of
                               the screw-cups. One
or more zinc plates rest against the side of the  vessel,
and are in contact with the mercury below.   A curved
wire is seen descending through  the liquid, insulated
by a glass tube, to the mercury, which it connects, in
 
COPPER  DEPOSITED.          57
 common with the zinc, with the plate on the top and
 the other gcrew-cup.   This battery will operate if
 simple scraps of zinc are placed in the mercury.   The
 mould in the depositing cell will be seen to be con-
 nected with the zinc or negative pole of the battery.
    90.  During  the solution of the  positive  plate, a
 considerable quantity of black  matter is left, mostly
 carbon, which would  injure the copy if allowed to
 fall on the mould.  It is, therefore, best to place both
 in a vertical position,  the face of  the mould  being
 opposite  the piece of copper.   The  solution may be
 stirred occasionally, to keep its  upper and lower parts
 of equal strength.
   91.  When  the process is  going  on well,  the de-
 posited metal  will  be  of a  very light copper  color.
 The rapidity of the deposition  depends greatly upon
 the temperature ;  the process  proceeds  much faster in
 warm weather than in cold, and  still more so if the
 solution be kept hot.  A thickness of one tenth of an
 inch may require from  three days to a week for its
 formation, when artificial  heat  is not used.   When a
 sufficient thickness has  been  attained,  the copy may
 generally be removed from  the mould without dif-
 ficulty, care being taken to cut away any copper
 which embraces the mould  at  the  edges.
   92.  Every ounce of copper deposited requires the
 solution  of somewhat more  than an ounce of  zinc
 from the zinc plate of the  battery.  Five or six elec-
 trotypes may be  made  at once,  without increasing
this expense, by arranging in succession several ves-
sels, each  containing a mould  and a copper plate con- 
58             DAVIS'S  MANUAL.

nected by  a wire with  the mould in  the  next one.
The plates of copper and the moulds  should all  be
nearly of the same size, and the solution should con-
tain  less blue vitriol and more  sulphuric  acid than
directed  in <§> 88,  particularly  if the  series  extend
beyond two  or three.   When the moulds  are small,
glass tumblers  form  the most convenient vessels.
Fig.  33 illustrates this arrangement,  in which one
battery is seen  connected with three depositing cells.
                       Fig. 33.
The  moulds will  be observed  to  occupy the same
position in relation to the current in each of the cells.
The  copper plates  opposed to the  moulds  are  dis-
solved  in  proportion to the amount  of copper de-
posited,  so  that the  solutions  retain  their  strength
by the recomposition of sulphate of copper, exactly
equal  to the  decomposition at  the  surface of the
moulds.   The increase  of the number of cells re-
quires,  therefore, no increase  of electrical  energy,
except for  the greater distance through the  solutions
which the  galvanic current has  to pass.  In this way
several ounces of copper are obtained, with but a 
ELECTRO-ETCHING.
59
slight increase in the quantity of acid or blue vitriol
required for working the battery, and a little more
corrosion of the zinc plate.
   93. The surface of the electrotype copy is  usually
of a bright copper color; but sometimes it presents a
dull surface.   If it  is discolored, it may be cleansed
by immersion for  a few  moments in  dilute nitric
acid,  and then  washed with  water.   It may  be
bronzed by brushing  it over  with  blacklead  im-
mediately  upon its  removal  from the  solution,  and
having heated  it moderately over  a  clear fire,  by
rubbing it smartly with  a brush, the slightest mois-
ture being used at the same time, in order to remove
the black  lead.  It  may also be gilt  or silvered.
   94.  If the copper plate  which is opposed  to  the
mould in the solution is coated with wax, in which
lines are drawn reaching the metal, it will be  etched
by the acid, and may  afterwards  be  printed from
like a plate  etched  in the  usual way by nitric acid.
There is  the peculiar advantage in this process, that
the action is perfectly regular over the whole plate,
or that a gradation of action may be  produced by ap-
proaching  the  negative  pole  to  the  parts where  the
shades require to be bitten in deepest.   There are also
no nitrous fumes evolved, as with nitric acid.  A plate
of electrotype  copper is  preferable  to  any other for
etching, as  its purity insures an equal  result.  The
negative pole should be  small, and  at some distance
from  the  plate  to  be etched,  when it  is intended
that it shall act  uniformly.
  95.  A process of surface-printing, called Glycog- 
60
DAVIS'S  MANUAL.
raphy has recently been devised, by a reverse opera-
tion  to that of galvanic etching.   A design is drawn
through  an  etching ground upon a polished plate,
as before;  the  whole is  then blackleaded,  and  a
plate of copper thrown down,  in which the lines of
the drawing are of course raised like  those  of  a
wood cut.   This plate is  printed from, like  an en-
graving on wood, in the same page with common
type; which cannot, be done with  a copper plate or
steel plate engraving.
   96.  It is sometimes desirable to precipitate copper
on iron or steel, to prepare it for receiving the noble
metals, or for acting as a mould in the common sul-
phate  of copper  solution.    The  solution used for
this purpose  is the cyanide  of copper, which is not
decomposed by  iron, and which is prepared by dis-
solving oxide of copper, or sulphate of copper, in  a
solution of cyanide of potassium.  This salt  is only
useful  for throwing down a film of copper upon iron
or other  oxidizable  metals.   The  surface of the iron
must be perfectly clean.
   97.  Copper is the only  metal which can be  used
with advantage  for the  purposes  which  have  been
described.   The precipitation of the  noble  metals,
silver, gold, and platinum,  is of great importance for
purposes of ornament and  protection to other  metals.
Their salts give  water a high  conducting power, and
are themselves  easy of decomposition.   There is,
therefore, a  great tendency to the evolution  of hy-
drogen, and  this  evolution is peculiarly  liable to
reduce the metal as a black powder.   It is as yet 
   ELECTRO—GILDING  AND  SILVERING.  61

almost  impracticable  to reduce  platinum  in  other
than the  divided  state,  which has, however, an im-
portant application in the coating  of  platinum plates
for batteries, where  it  prevents  the  adhesion  of
hydrogen.  The solution used for this purpose is the
chloride  obtained by dissolving  platinum  in  nitro-
muriatic acid, and partially evaporating to expel any
great excess of acid.   The solution  may be subse-
quently diluted to any required amount.
   98.  The  battery  used for gilding  and silvering
consists of from three to six or eight  pairs, according
to the extent of surface to be covered, and the resist-
ance offered  by the  solution.  As  the solutions  grow
older,  they require  less power to decompose them;
but  there is then a greater  tendency  to  the  black
deposit.    The  positive pole usually employed  is a
platinum  wire,  or  pointed  strip  of  platinum  foil.
This is  not dissolved  by the solution, and conse-
quently  the  electro-negative element of the salt has
                       Fig. 34.
to be evolved, instead of entering into a new com-
bination.   It is  on  this account that several pairs
have  no more efficiency in  decomposing  the solu-
tion than  one pair where  the positive  pole  is dis-
solved.   The object of the  present arrangement is
              6 
62
DAVIS'S  MANUAL.
to bring the whole action more exclusively under
the control of the  battery, and to avoid local action.
For  ordinary purposes, a  Smee's  battery, weakly
charged, is  preferable.   Fig.  34 represents an odds
and ends battery of this kind,  connected  with the
silvering apparatus, differing only from that described
in $ 89 by being uncovered.   It  will  be observed
that  the positive pole,  in  the decomposing cell,  is
placed at a distance from the object to be silvered.
  99.  Another  form of  Smee's battery,  connected
with a  depositing  apparatus for silvering  daguerreo-
type plates,  is exhibited in  Fig. 35.   This is the
                       Fig. 35.
same form with Grove's battery, the porous cylinders
only being removed.   The platinum  plates are at-
tached to little arches of  wire, which  enter  small
holes  in  the  zinc, into which  they may be wedged
or from  which  they may be  removed at pleasure.
In the depositing cell, a daguerreotype plate, D, is
seen attached by its edge to a screw-cup and clamp
prepared for that purpose, and thence connected with
the terminal zinc cylinder of the series, Z.   Opposed
to the daguerreotype plate, is a plate of silver, S, con-
nected with the platinum pole, P,  of the battery,  and 
ELECTRO —GILDING  AND SILVERING.  63
which is  dissolved by the  solution in proportion as
silver is deposited on the daguerreotype plate.  A
very pure coating of  silver is thus given to a  plate
from  which  the  best  pictures are obtained.
        This fig. shows the porous cell belonging to
      the  battery  when used as a  Grove's.   The
      use of this cell, and of nitric  acid within it,
      constitutes the difference between these forms.
   100.  Fig. 36  represents a series of the sulphate
of copper  battery  applied  to gilding  and  silvering.
                       Fig. 36.
This may be used where a very large surface is to be
deposited upon.  The figure is intended to illustrate
chiefly the deposition of alloys by the galvanic cur-
rent.   If two metals are contained in a solution, the
general law is, that the  one most easily reduced  by
the electrical process will be deposited first, and in a
state almost  absolutely  pure.  If the energy of the
current,  however,  is very much  increased, all  the
metals present will go down  in variable  proportion.
Thus,  if there is a  little  silver  in the gold electrotype
solution, a feeble current will  throw down the silver
first;  if  there  is   copper present, and  no silver, a 
64
DAVIS'S  MANUAL.
feeble current will throw  down a pure yellow deposit
of  gold,  while a stronger one  will throw  down a
reddish metal  resembling the gold of jewellers  and
of the mint.
   101.  The salt of silver, used for precipitation,  is
the  ferrocyanide.   A  silver dollar is  dissolved in
nitric acid, and the silver precipitated in the state of
chloride,  by muriatic  acid  or  common  salt.   The
precipitate is washed, and then  added  to  a  sufficient
quantity of a hot saturated solution of ferrocyanide
of potassium (yellow prussiate of potash), to dissolve
it.   Sufficient water  is  then  added to  make  two
quarts.   The solution may  be  poured  off  from  the
sediment which remains,  or it may be used at once.
It must be remembered that  the salt employed con-
tains  cyanogen, the active principle of prussic acid.
Prussic  acid itself and oxygen are evolved at  the
positive pole during the  decomposition.   A  solution
of cyanide of silver may also be used,  which is  ob-
tained by  dissolving  the  precipitate of  chloride  of
silver, mentioned  above, in  cyanide  of potassium,
instead  of the  ferrocyanide.  In this case,  the solu-
tion of cyanide of  potassium need not be so strong,
or be raised  above the common temperature.  Only
sufficient of the cyanide of potassium need  be added
to take up all the chloride of silver.
  102.  The solution of gold employed is the cyan-
ide.   This is made by dissolving a  five dollar piece
in nitromuriatic acid  (a  mixture of one measure of
nitric acid with four of muriatic), and evaporating the
salt very carefully,  in order to drive off the excess of 
   E LE CTRO —GILD ING  AND  SILVERING.  65

acid.   This is then redissolved  with a sufficiency
of cyanide of potassium  to give  a clear solution, it
requiring  somewhat less than an ounce of the cy-
anide for  this purpose.    Enough water is  added to
make two  quarts.  As  a  general rule, it requires
more battery  power for  gold than for silver.  The
addition of a  small quantity of cyanide of potassium
to a  solution of  gold  diminishes the tendency to
black deposit  where this  is  exhibited, and where the
fault  is referable  to the solution.
   103.  It is necessary that the  surface on which a
metal is deposited should  be perfectly clean, and free
from a film of air, that it  may adhere; and the metal
should  be thrown down with sufficient energy to
prevent any local  action with the mould.   The arti-
cle to be silvered or gilded may in some  cases be
cleaned by a  solution  of potash; but the deposit is
more certain to adhere  if the  surface is rubbed with
a  little  rottenstone when first placed in the metallic
solution, and  connected  with  the  battery.   When-
ever, during the process,  the deposit becomes discol-
ored or rough, the  negative  plate  should  be taken
out,  and brushed with a little whiting and  soap and
water.  The  thickness  of  the  coating  of  gold and
silver is proportional to the  time  occupied by the de-
position and the amount  of electricity which passes.
For  the same amount  of electricity, 32 grains of
copper,  108 grains of silver, and 99  grains of gold,
are deposited, these being  the chemical equivalents
of those metals.
   104.  If a small object, such as a dial of  a watch,
              6* 
6b
DAVIS'S  MANUAL.
 be placed in a solution of cyanide of silver or gold in
 a capsule, the metals will be thrown down  upon  it
      Fig. 37.     in a very  satisfactory manner, if a
                 small  slip of zinc  be placed  in con-
                 tact with  it, as represented by Z in
                 Fig.  37, and the  whole  be heated
                 by a  spirit-lamp.   It is  necessary
                 that  there should  be rather  more
                 cyanide of potassium in the solution
                 than in that for the ordinary process.
                 The dial of the watch itself becomes
                 here one plate of the battery,  and the
                 slip of zinc the other.  The zinc is
 dissolved by the  solution; but by the law regulating
 the deposit of alloys, only  gold  is thrown  down by
 the feeble current which is excited.
   105.   When a  solution of  acetate  of lead  is de-
 composed, a very beautiful result ensues at the posi-
 tive pole.  To exhibit  this, a  large polished metallic
 surface is connected with the positive wire in the solu-
 tion,  and a fine  negative  pole is brought near  to it.
 Metallic  lead  is  precipitated on  the negative  wire,
 and at the same  time  a precipitate of deutoxide of
 lead   takes  place on  the  positive  plate,  exhibiting
 concentric rings   of prismatic  colors,  owing  to the
 different  thickness of  the coating of oxide.  These
 depositions have received the name of metallic chromes.
 In this instance,  the oxygen about  to be  evolved at
 the positive pole  unites with  a  portion  of the  pn>
 toxide of lead in solution, and the resulting deutoxide
appears  on the surface of  the plate.  Instead  of a 
           THERMO-ELECTRICITY.         67

fine negative wire, a spherical body connected  with
it may be approached  to  the  positive plate, the dif-
ferent  distances  of its  parts  producing a  beautiful
gradation of oxide.
            III.  THERMO-ELECTRICITY.

   106.  The term  thermo-electricity expresses a form
of electricity developed by the agency of heat.   It
was  discovered  by Professor Seebeck, of Berlin, in
1822, that if the junction of two dissimilar metals
was  heated,  an electrical  current  would flow from
one  to the  other.  Thus, if the ends of two wires,
or strips of  German silver and brass,  are  made to
touch each other,  or are  brazed  together, and  the
junction heated, a current  will flow from the German
silver to the brass, if  the free extremities of the wires
are connected  by any conductor  of electricity,  and
an electrical circuit will be established, as the  gal-
vanic circuit is established  by  connecting the poles
of the battery.   In the cut, Fig.  38,  G represent?
the German silver, and B the brass;  the direction of
the current being indicated by  the  arrow?.
   107.  In  thermo-electricity, as  in  galvanism, in-
stead of two  metals,  one  metal, in  different  con- 
68
DAVIS'S  MANUAL.
ditions, can  be  used to  excite  a current.    lhus
merely twisting  the  middle of an iron or platinum
wire, and heating it  on one side of the twisted por-
tion, will  produce a  current, flowing, at the heated
part,  from  the  'untwisted to the  twisted portion,
when- the extremities are  connected.
   108.  A  current  may also be  excited  with two
wires of the  same metal, by heating  the end of one,
and  bringing it in  contact  with the  other.   It is
difficult to succeed in this experiment when metals
are used whose  conducting  power for  heat is  great.
Thus  copper or silver  wires produce a  very  feeble
current; but iron  or  platinum  an energetic one,
especially when the ends,  which are  brought in con-
tact, are twisted into a spiral.  The direction of the
current at the junction is from the cold  to  the hot
wire;  and  it ceases  as  soon as  an equilibrium  of
temperature is established  between the two.  A con-
siderable  current is  also  produced by heating  the
junction of two  platinum wires of different diameters.
The current flows  from the  fine  to the coarse wire,
whether the heat is  applied at the point of junction
or to either wire at a  little  distance from it.  In large
arrangements, plates  or strips  of dissimilar metals
are generally used.
   109. The  thermo-electric current,  thus  excited
between two metals,  is generally referred  to the dif-
ference in  their  conducting power for  heat, and to
the different orders of crystallization to which their
particles belong, the  laws  of  crystallization  being
supposed to result from the electrical character of the 
           THERMO-ELECTRICITY.         69

particles.   Where the same metal, in different  con-
ditions, is  used,  the  production of electricity is re-
ferred  to the  unequal propagation of heat on  each
side of the  heated point,  caused in the single wire by
the obstruction occasioned by  the  twist, and in the
case of two wires, by the contact of the cold wire, or
where  they are connected together, by the difference
in their diameters.   The causes, however, have not
yet been fully investigated, and many points are in-
volved in great obscurity.
   110.  Metals differ  greatly in their power to excite
a current, when associated together in thermo-electric
pairs.   Some  of the  peculiarities  in the combina-
tions of the more useful  metals will be stated.   It is
necessary,  however, to say a few words with regard
to the galvanometer,  an instrument  to  indicate  or
measure electrical currents, and which will be more
fully described in Chapter I. Section 2.  A current
of electricity, passing through a wire, is found to de-
flect a  magnetic needle in its neighborhood.   By an
                      Fig. 39.
arrangement  such as Fig.  39,  where  G is the gal-
vanometer, consisting of a  magnetic needle in close
j 
70
D AVI S ' S  MANUAL.
proximity to a coil of wire, above which is fixed a
graduated circle, the direction of an electrical current
made to pass through  the wire  is indicated by  the
deflection of the needle  from the north  and south
line, in one direction  or  the  other, and its  strength
is measured by the number of degrees to which it
is deflected.   The  deflection  of  the  needle will be
frequently  referred to  hereafter.  When  using  this
instrument, the  zero points  of the graduated circle
must be placed  north  and south, so  as to lie in  the
same direction as the  magnetic needle above them
does when influenced by the earth's magnetism alone.
In the figure, a  thermo-electric  pair,  of bismuth and
antimony,  heated  by  a  spirit-lamp,  is  shown in
connection with the galvanometer.   The  arrows in-
dicate the course of the current  from the antimony,
A,  to  the  bismuth, B, in the  exterior  circuit; its
direction being  of  course  the reverse of  that  at  the
junction, where it  flows  from B to  A.
   111.  The  character  of the juncture between  the
plates or  wires  has an important influence on  the
amount of  the  current with the  same  metals.  Fre-
quently, when the elements of  the  pair are merely
made to touch each other, the current is greater than
when they are  brazed or soldered together.   Gen-
erally, the slighter the connections  are,  the  better.
They must be sufficient to conduct all  the electricity
generated, but no more; for if they are unnecessarily
large, they allow  the  electricity to return to  the
metal whence it proceeded, without passing through
the  exterior  circuit. 
        THERMO-ELECTRIC   PAIRS.      71

  112.  The  metal from which  the current proceeds
through the heated junction is analogous in situation
to the zinc, or positive plate, in the  galvanic pair, from
which the current  proceeds through the liquid of the
battery, as described in § 16.   The metal to which
the  current proceeds, through  the  junction, is analo-
gous to the  copper, or negative  plate.   The positive
pole of the  thermo-electric  pair is the extremity of
the  negative  metal, as the copper pole is the positive
pole of the  battery.   The  negative thermo-electric
pole is the extremity of the positive metal.   In the
observations  and  table which  follow, the  positive
element  of  the pair,  answering  to  the zinc  in  a
galvanic pair, will always be named  first.
  113.  German Silver and  Antimony.—The cur-
rent excited by these is greater  than that from  bismuth
and antimony at the same temperature.  Their junc-
tions  being  put into  hot oil, of a fixed temperature,
and the free ends of the plates connected  with the
galvanometer used  in these  experiments, the bismuth
and antimony occasioned a constant deflection of the
needle of 75° ;  the German silver and  antimony,  a
deflection of 85°:  the heat  being  increased with the
bismuth and antimony to  the melting point of bis-
muth, the  deflection  was  82°, while the  German
silver  and antimony,  heated  in a spirit-lamp,  gave
a deflection  of 88°.
  114.  Bismuth  and Antimony.—Plates  of these
rr.etals have  been heretofore  generally used in  large
thermo-electric  arrangements.   The current excited
by  heating their junctions is greater than. from many 
72
DAVIS'S  MANUAL.
 other metals, when a feeble heat  is used ;  but from
 the fusibility of bismuth, the heat can never be raised
 very high.
   115.  German Silver and Carbon.— A current of
 considerable energy is produced by this combination.
 In this and in the succeeding experiments, where the
 use of carbon is mentioned, the kind employed was
 the  gas-carbon deposited  from carbureted hydrogen
 in the retorts of the gas-works.  This substance lines
 the upper part of the  interior of the retorts in com-
 pact layers, and  is entirely different from coke, which
 is the residue from the  coal, after its gas has been
 expelled.   It is  nearly or quite pure  carbon, and is a
 better conductor,  both of heat  and  electricity, than
 ordinary charcoal.
   116.  German  silver  is an  alloy of nickel with
 copper  and  zinc, containing in  100  parts,  50  of
 copper, 30 of zinc, and  20 of nickel.  It  is used  in
 many of the thermo-electric  instruments, which will
 be hereafter described.   German silver is  positive  to
 all  the  metals that have been tried, even to  nickel
 itself; with the  exception of bismuth, to which  it
 is negative.
  Carbon and Silver,  or Iron. —In  these combi-
 nations, and  also with antimony, the carbon is pos-
 itive, the current  being  rather feeble.
  117.  The deflections given in the following table
admit of comparison with each other to a consider-
able extent, though not so strictly as if  wires of the
same size had been employed in all the experiments.
It must be  remembered, too,  that as the needle 
        thermo-electric  pairs.      73

approaches the extreme  angle  of deflection, 90°,  a
much greater  increase  of the current is  required to
carry it  a few degrees  farther  towards 90°  than
when it  is near the zero.   Hence,  a deflection of
40°  does not  indicate  a  current  of  half the power
of one of 80°, but  considerably less.  Nor can mo-
mentary  deflections be  compared  with permanent
ones, in  estimating the power  of the  current;  as  a
current which, by its first impulse, causes the needle
to traverse a  large arc,  may not be  able to main-
tain  more than a few  degrees  of steady deflection.
Current	FLOWS THROUGH HEATED JUNCTION.		Deflection of
From positive		To negative.	the Needle.
German Silver, . . .			88°
German Silver, . . .			85°
German Silver, . . .			85°
German Silver, . . .			85°
German Silver, . . .			85°
			85°
German Silver, . . .			85°
		Zinc,..........	84°
German Silver, . . .			81°
German Silver, . . .			82°
Silver,........			88°
Bismuth, . .			82°
Bismuth,. .			78°
Bismuth,. .			85°
Bismuth, . .			85°
Bismuth, . .		. . German Silver, ....	83°
Platinum, .			78°
Carbon, . .			75°
  118.  The actual, though not the relative, amount
of the deflections, will vary with the  galvanometer
              7 
74
DAVIS'S  MANUAL.
employed.  In  accurate experiments, the  arrange-
ment should be  such that  the deflections shall  hot
exceed  20°.   Within this limit, the deviation of an
astatic  needle  from  the zero point is  strictly  pro-
portional  to the  quantity of electricity circulating.
   119.  The wires were not soldered together, but
their ends were brought in contact  before the appli-
cation of the heat, and kept  so  to the  end of  the
experiment.   With  the  more fusible  metals,  the
greatest heat  was  employed which  was consistent
with  their fusibility.   The object  was  to produce
the greatest  current  that  could easily  be  obtained
from each combination.   It will be found that there
is  an entire  difference between the  series of posi-
tive  and negative  metals for thermo-electricity and
for galvanism.
   120.  In some  cases, the direction  of  the current
is reversed, either by raising  the heat at the junction
to a high degree,  or by heating one  metal more than
the other.  The following are instances of this kind.
The metal of each combination, which is positive
at low temperatures,  is named first.   Increasing  the
temperature of the negative metal  generally increases
the amount of deflection  produced  by heating the
junction;  while,  if the higher heat  is applied to the
metal which is  positive at  moderate  temperatures,
a  current in  the  opposite  direction  is  established.
The direction of the current in these combinations
is, however,  often uncertain,  and  the  few experi-
ments which have been  made afford  no  explana-
tion  of the cause of the changes. 
       THERMO — ELECTRIC  CURRENT.     75

  121.  Iron and  Platinum. — When heat is applied
to the junction, or to  the  platinum a little  one side
of it, a deflection of  about 50° is obtained; when
to the iron  near the junction,  or when  the  junction
itself is raised to a red  heat,  the direction of the
current is  immediately reversed, it  now flowing from
the  platinum to  the  iron,  and  the needle  is de-
flected 60°  or 70° in  the opposite direction.
   122.  Copper and Iron. — With fine wires the cur-
rent is feeble, with large  ones tolerably powerful.
The deflection is  increased by heating the iron near
the junction.   When the junction is raised  to a red
heat, the  current  is reversed, and  still more readily
when  the heat  is applied to  the copper near it.
   Silver and Iron. — Deflection  considerable.   On
heating the  silver, an energetic current ensues in the
opposite direction; also, in a -less  degree, by raising
the junction to a red heat.
   Brass and Iron.—Current moderate ;  reversed at
a red heat, and  still  more  effectually  by  heating
the  brass.
   Zinc and Iron.—Current moderate, and on heat-
ing  the zinc  near the junction to its melting point,
changes its direction.
   123. Platinum  and   Silver. — Deflection  70°.
On  heating  the platinum,  a strong  current  flows in
the  opposite direction.
   Brass and Silver. —The  current is reversed at a
red  heat, or by applying the heat to the brass, near
the  junction.
   124. In quantity, the thermo-electric current much 
76
DAVIS'S  MANUAL.
resembles a feeble  galvanic current.  In intensity, it
is  somewhat less.   In a single  galvanic  pair, elec-
tricity is  set in  motion in a  certain direction, and
cannot return in  the same  path to the zinc, from
which it proceeded, without  passing  through  the
fluid between the plates, which is a poor  conductor.
It  is, therefore, partially,  though very imperfectly,
insulated.  In a  thermo-electric  pair, the electricity
is  set  in motion from  one  of  the  metals to  the
other, through the  metallic junction.   Here there is
no  insulation.  The current  flows  through  a good
conductor, and can  only be  the excess of the force
which sets the  electricity in motion over its constant
effort to  return to equilibrium.   It  is  probably for
this reason  that  the intensity of thermo-electricity
is  less than that of galvanism.
   125.  A single  galvanic and  thermo-electric pair
were taken, each of which deflected the needle 75°,
permanently.   The galvanic current was then made
to flow through  a hundred  feet  of fine  steel wire
1-150 of an inch in diameter.   From the  poor con-
duction of the wire, the  deflection was reduced to
60°.  With  the  thermo-electric  pair,  it was  found
that the  needle was deflected  60°, when the current
passed through only fourteen  feet of the wire.  As
the conducting power of a wire  is in proportion to
the  intensity of  the  current, the  intensity of  the
thermo-electric current  in  this  instance was  equal
to one seventh of that  of the galvanic current.
   126.  In  soldering the  wires  or  plates   together,
they  are  not usually connected  in  a straight) line| 
THERMO-ELECTRIC  SERIES.     77
but at an acute  angle with each other.   If several
of these  single pairs are associated together consec-
utively, that is, by connecting the German silver of
the one  to the brass of the next, or the bismuth of
one to the antimony of the next, and so on, we have
a thermo-electric  battery, in which the power  of the
current is exalted as by the successive pairs of plates
in a galvanic battery.  It will  be understood that in
these  cases  there  is German silver and brass alter-
nately, or  bismuth  and antimony  alternately,  &c,
throughout the whole series.   For the sake of com-
pactness, the wires or plates are laid side by side, and
soldered  by their  alternate  ends, while  they are in-
sulated or  separated  from each  other by  paper or
pasteboard, which prevents any passage of electricity
from one to the  other, except through the junctions.
   127. A thermo-electric series of considerable pow-
er may be constructed of strips of German silver and
brass.  It will bear contact with red-hot iron, and is
very compact.   Strips of  pasteboard are interposed
between  the  adjacent  metals.   Fig. 40  represents
such a series, consisting of ten  pairs.  When several
                      Fig. 40.
pairs  are connected in this manner,  it is necessary
that  the junctions should be  somewhat larger  than
in the  case of  a single  pair.  Then, the  slighter
              j *
88888888 
78
D A VI S ' S  M ANU A L.
the connection  the  better;  but as the current  has
to flow through all the junctions in a series of pairs,
the electricity generated would scarcely be conducted
through  them at all,  were they all imperfect.  By
heating the  junctions of the strips  at one end  of  the
series with a spirit-lamp, a current is produced which
increases  or  diminishes as the heat is applied,  de-
pending  altogether  for its existence  on  the  differ-
ence of temperature in the  opposite junctions.   On
grasping the junctions, at one end,  in the  fingers,
even  the warmth of the  hand produces  a sensible
effect.   It is evident that, if  the  junctions at both
ends of the series were equally  heated, currents would
be  produced  in  opposite  directions,  which  would
neutralize each  other.
   128.  Thermo-Electric Battery.—In  Fig.  41
is represented a thermo-electric battery, composed of
sixty pairs of plates of bismuth and antimony, each
three inches long, three fourths of an inch broad, and
one fourth of an inch thick.  They are arranged side
by side, in a metallic  case, B, so that one series of
junctions, underneath the battery, may be heated by
the radiation of a hot iron plate, E, the edge of which 
       thermo-electric  battery.     79

is seen underneath the battery in the cut; while the
opposite junctions, seen at A, are kept cool by water
or ice placed in the receiver, which forms the upper
part  of the battery.   A  still greater depression  of
temperature is  produced  by  a  mixture of snow or
pounded  ice, with half its weight of common salt.
In order to make the receiver sufficiently water-tight,
as well as to insulate the plates from the case, they are
cemented into  it with plaster.  Refrigeration at one
end of the bars, as would  be  anticipated, is found to
produce a current in the same direction, and equal to
that  which would be produced by a similar excess of
heat at the other end; difference of heat at the differ-
ent ends, however produced, being the occasion of the
current.  By associating both of these causes in this
battery, there  is a corresponding  increase of power.
As the metals  employed  in the battery  are  fusible,
the radiant heat of the iron ought  never to exceed
300° Fahrenheit.  The  iron  plate being laid  upon
a large tile, the  battery  is placed over it, the  iron
being pretty near the ends of  the  bars, but not in
contact with them.
   129.  The terminal  plates of the battery are con-
nected with two  screw-cups,  passing through the
metallic  case,  and  insulated  from  it.   In the  cut,
the battery is seen in connection with an apparatus,
which will hereafter  be described, by which the
magnetizing power of the current is shown.  The
ends of the coil of insulated wire, C, being fixed in
the cups, the current is  obliged to traverse the coil,
and  the two semicircular bars  of soft iron,  seen at 
80
DAVIS'S  MANUAL.
 D, are held together, by the magnetism thus induced,
 with  so  much  force as to  require a weight of forty
 or fifty pounds to separate them.   This battery has
 sufficient power to give shocks and sparks, and pro-
 duce  various magnetic phenomena,  with the  appro-
 priate apparatus,  which will be described hereafter,
 when the principles on which those effects depend
 have  been explained.
   130. By forming a compound thermo-electric bat-
 tery of a number of slender bars of antimony and
 bismuth,  soldered together  by their alternate  ends,
 an instrument is obtained far  more susceptible  to
 slight  differences  of  temperature than the  mercurial
 or  air thermometer.   Such is  the  construction of
 Melloni's  Thermo-Multiplier.   It consists  of  about
 fifty little bars of  the two metals, enclosed  in a brass
 cylinder, one half or one third of an inch  in diameter,
 and two and  a half inches long.   The  terminal bars
 or poles of this little  battery are connected by wires
 with  a delicate galvanometer.  When the ends  of
 the bars at one extremity of the cylinder  are exposed
 to any source of heat, while the temperature of the
 other ends remains unchanged, an  electric current
 is  excited which  deflects  the  needle of the galva-
 nometer more or less in proportion to the heat.   The
 radiant heat from the  hand brought  near  the battery
 is  sufficient  to  move the  needle several  degrees.
 This  instrument  was  employed by  Melloni in his
important  researches on the  transmission of radiant
heat from different  sources  through various trans-
parent  and translucent bodies. 
           PRODUCTION  OF  COLD.         81

   131.  In thermo-electricity, an electrical current is
produced  by heating  unequally the opposite ends of
metallic plates, associated in a thermo-electric series.
The converse of this is found true.   If a galvanic
current  is made to pass through the same  series, the
opposite junctions will acquire heat on the one side
and  lose it  on the other.
   132.  Fig. 42 represents an instrument for showing
the simultaneous  production of heat and cold by the
           Pjv 42.            galvanic  current.   It
                             consists of three bars,
                             two  of bismuth and
                             one  of antimony, ar-
                             ranged as seen in  the
                             figure,  where the anti-
                             mony is  shown at  A,
                             and  the  two  bars  of
                             bismuth at B and B'.
The bars  are  soldered together under the bulbs  of
two air thermometers, T and T', a little cavity being
made to  receive  the  bulb of  each thermometer; a
drop of water is put in each cavity, in order to facili-
tate the conduction of heat from the metals to the ther-
mometers.   The galvanic current being sent through
the metals, in the  direction  indicated by the arrows,
from the bismuth B', through  the  antimony, to  the
other bar of bismuth,  and thence back to the battery,
cold  is produced at the junction of A with B', as will
be indicated by the thermometer  T', and heat at  the
junction between  A and B, as the thermometer  T
will show.   By reversing the direction of the battery
 
82            DAVIS'S  MANUAL.

current, the effect  on the  two thermometers will be
reversed.
  133.  The elevation  of temperature  produced  is
always greater than the depression;  this difference
is probably due to  the low  conducting power of
the  metals for electricity,  which causes them to be-
come slightly heated by the current — a phenomenon
altogether distinct  from the heating of the  junction
by it.  It will be observed in the figure that the cur-
rent  has the same  direction as that which would be
produced, were  the  battery removed,  by the appli-
cation  of  heat at  the junction of A with  B', or of
cold  to that between B and A; the current which
produces  heat flowing  in the opposite  direction to
the  current which would be  produced by  it.
            IV.  ANIMAL  ELECTRICITY.

  134.  This name has been applied to the electricity
developed in the  organs of certain  fishes.   These
organs are found, by anatomical examination, to con-
sist of  numerous  cells,  arranged  in  columns, and
divided by septa or  small discs, so as to suggest  at
once  the idea of a  galvanic arrangement.  Further
observations show  that they are supplied with large
branches from the  nervous system, so much so, that,
in the torpedo and  gymnotus, the ganglia and nerves
belonging to the electrical apparatus exceed  in ex-
tent all the rest of  the nervous system of the animal.
It is  also found that this manifestation  of electrical 
           ANIMAL  ELECTRICITY.          83

power  is subject to the  nervous system, and con-
trolled by the will.   An actual connection, therefore,
exists here  between the  vital and  electrical  phe-
nomena.   Several  cases  have recently been  authen-
ticated, in which electricity has been evolved by the
human subject  in a  state of nervous  disorder.   The
animals  naturally  endowed  with this  power  are
surrounded by  a conducting medium, water, which
enables  them to paralyze  other  creatures in their
neighborhood, which thus become their  prey.
   135.  There is a remarkable analogy between this
production of electrical force  and the production of
muscular force   in the ordinary contraction  of  the
muscles.   In both cases, the power which is devel-
oped is inherent in the organ where it is manifested,
and in both the  power is controlled and exercised by
the agency  of  the will or influence  of the  nervous
system.   Liebig has suggested a theory of muscular
action, which supposes that the contractile force  of
the muscles  is  due  to a  principle set free  by  the
oxidizement of the animal tissues by the blood,  in
the same way that  electricity is set  free  by the  ox-
idizement of zinc.   He supposes that, when a mus-
cular contraction takes place, the nerves, supplying
the part, withdraw their vital protection,  and oxida-
tion  under the  chemical laws, and  the  consequent
development of force, result.   An  evidence  relied
upon in  support of this  theory is the waste  of ani-
mal substance which occurs  proportional to muscular
action.   A further application of this theory would
extend it to the electrical organs of fishes,  where, 
84
DAVIS'S  MANUAL.
 by oxidizement  of tissues,  suitably arranged, elec-
 tricity  itself,  instead  of muscular  force, would be
 eliminated, when the protecting agency of  the  ner-
 vous  system was withdrawn.   An illustration  of the
 supposed active  and  passive  states of  the  animal
 organs under the nervous control may be readily found
 in Smee's  battery, where the plates remain  opposed
 to each other without any action until the circuit is
 completed, when an electrical discharge at once takes
 place.   However hypothetical the views of Liebig
 may be, they may  be useful as connecting together
 some  phenomena belonging to a very dark and  un-
 explored field of science.  The analogy of the  action
 of the will or nervous system in producing, in  the
 one case, muscular,  and in the other electrical action,
 is at any rate an important one.    In the diseased
 human  subjects  which  have been mentioned,  the
 development of muscular force seems to have been
 changed into a development of electricity.   We have,
 as yet, no  knowledge of the relation between these
 two principles.   Professor Renwick  has, however,
 remarked, "In these electric fish we behold nervous
 power  converted into  electric force;  it cannot be
doubted that the converse of this is possible."
  136.  The Gymnotus is found in the fresh  waters
of South America.   It is  interesting as having been
the subject of  a series of experiments by Faraday, in
 which  the  phenomena of magnetism, electrical  de-
composition, the  production of heat, the  shock and
spark were all obtained.  Fig. 43 represents an indi-
vidual of this  species, which was preserved alive for 
GYMNOTUS.                85
some  time  in  this city.   The upper figure  gives a
lateral view, the lower one a view from above, with
the hand in a favorable position to receive a  shock,
passing  from the anterior  to  the posterior  part of
the animal, through  the  surrounding water.  It will
readily be comprehended, that, even when the animal
is  in  a straight position, the  finger placed near its
              8 
86
DAVIS'S  MANUAL.
 side will become the medium of the passage of elec-
 tricity, as it is a better conductor than  water, and the
 current between the  extremities  extends to some
 distance  from  the  animal.    The  electricity  passes
 through the finger in this case, only from one side to
 the other, but still, by acting on the local nerves, pro-
 duces the sensation of a considerable shock.   When
 a finger of one hand is placed near the head of the
 animal, and  a  finger of the  other  near the  tail, the
 discharge passes through the arms and body,  and  a
 very powerful  shock  is  experienced.   WThen two
 fingers are thus placed in water, in the course of  a
 discharge of ordinary electricity, a shock is felt  in the
 same way; but in proportion as the water is made  a
 good conductor by adding salt, the effect decreases.
 Thus,  in the experiment (§52) with a leech or fish-
 worm,  if the water be made  a good conductor,  the
 animal ceases  to be troubled when  the  galvanic
 circle is  completed.   When a small fish was placed
 in the water with  the gymnotus, the  latter was
 observed  to curve  himself so as to bring the fish
 between  the extremities  of  his  body, and  then to
 make a discharge, which was either fatal or produced
entire numbness and rigidity.
  137. The  anterior region  of the body was  found
by Faraday to  be positive, and  the posterior  nega-
 tive, at the  moment of  discharge.  The electrical
organs  of the animal occupy almost its whole length,
with the exception of the anterior region.  It is pro-
vided with a beautiful fringe-like ventral fin, which
gives it great ease of motion.  It is found to  suffer 
TORPEDO.
87
great  exhaustion from  the frequent exercise  of its
electrical power, showing thus another link between
the nervous and  electrical systems.
   138.  The Torpedo, or Electrical Ray, is found
on the sea-coast in different parts of Europe.   A new
                      Fig. 44.
species Torpedo occidentalis, Storer, has lately been
taken at Wellfleet, Massachusetts.  It is represented
in the above figure.   They are described as vary-
ing in weight from 20 to 200  lbs., and  the shocks
which they give, according  to the testimony of fish-
ermen, are sufficient instantly  to  prostrate a  man.
These shocks are  also felt,  in  a less degree, by one
holding a harpoon or  rope, to which the animal  is
attached.  The electrical organs are situated on the
anterior and  lateral portion of  the  animal.   The
electrical lobes of the brain  are larger than the  whole 
88            DAVIS'S  MANUAL.

remainder of that organ, and the volume of the elec-
trical nerves greater than those supplying  all othei
portions of  the animal.
  139.  The Silurus  Electricus, the third of the
electrical fishes, is found in  the  rivers of  Africa.
In shape, it is elongated  like the  majority of fishes,
and  is  provided  with cirri,  or feelers,  about  the
mouth.   It  is believed that  the fishes of this  class
remain concealed near the bottom, and decoy  their
prey by waving these  cirri, so as to counterfeit the
appearance of worms.   This would give to the elec-
trical Silurus a great  advantage  in  bringing other
animals within the  scope of the  powerful  agency
with which it  is endowed. 
MAGNETISM.
                       i.

DIRECTIVE TENDENCY OF THE MAGNET.

     I.  IN REFERENCE TO ANOTHER MAGNET.

   140. Attractions and Repulsions. — The effects
produced by the opposite poles of a magnet, though
in some  respects  similar, are in  others contrary to
each other; the one attracting what the other repels.
Poles of different magnets, of the  same name, that, is,
both north or both south, are found to repel, while
those of an opposite name  attract each other.  This
is shown by  the following experiment.
   Let the south pole of a  magnet, N S, be brought
                         near to the north pole of a
                         dipping needle,  mounted
                         upon   a  stand,  as repre-
                         sented in Fig. 45.  The
                         needle, previously nearly
                         vertical,  will move  into
                         the position a a,  its north
                         pole  (indicated  by  the
head of the arrow  in the cut)  being attracted  by
             8*
 
90
DAVI S ' S  MANUAL.
the south pole of the magnet.   If, now, the magnet
be reversed, and its  north pole be made to approach
the corresponding pole of the  needle, the latter will
assume the position  r r, its north pole being repelled
by  that  of the magnet.   The south  pole  of the
needle, on the contrary, will be repelled by the south
pole of the magnet, and attracted by its north pole.
   141.  In place of  the  dipping needle,  a compass
needle,  or any horizontal magnetic  needle,  can be
employed.   A very fine  and  perfectly  dry sewing-
needle,  being previously  magnetized, and then laid
carefully upon the surface of  water, will float,  and,
being thus at liberty  to  move freely in any direc-
tion, may  be conveniently used to show the attrac-
tions and repulsions  described  above.   A larger
needle will answer  equally  well, if passed through
a  small  piece of cork, to enable it to  float.
   142.   The intensity of the  attraction or repulsion
exerted  between two magnetic  poles  varies in the
inverse ratio of the  square of their distance; that  is,
if the distance of the poles is doubled, the force with
which they attract or repel each  other  is reduced to
one quarter of its previous amount;  if  their distance
is trebled, to  one ninth; and  so on.   These attrac-
tions and repulsions  are not  affected  by the inter-
position of glass or metal, or any substance whatever
between the two  magnets;  unless  the  interposed
body is itself susceptible of magnetism.
   143.  In consequence of the mutual attractions and
repulsions exerted  between  the poles, a magnetic
needle, brought near to a fixed magnet, assumes cer- 
DIRECTIVE  TENDENCY  OF MAGNET.  91
tain determinate directions depending upon  the rela-
tive  positions of the two.   Thus,  in  Fig.  46, N S
            PY„.  4(3#            represents a stationary
                              /bar magnet,  and  the
                              three  arrows  indicate
                              the  directions  taken
 Bf               ~sTi^—i  —•.  by a magnetic needle
                             placed   in   different
                             positions.   The  two
needles  near  the soutli pole of the bar direct their
north poles towards it, the north pole of the stationary
magnet  being too remote  to influence them to any
extent.   But  the needle placed over the centre of the
bar has  its direction determined by both poles, and
assumes  a  position parallel to  the bar, but with its
poles  in  a  reverse  direction.
   144.  In  Fig.  47 are represented various directions
assumed  by a small movable  magnet brought near
                      Fig. 47.
to a stationary one.   These  may be readily observed
by carrying  a small  bar magnet, suspended  by a
string, or,  better, a magnetic needle, mounted  upon
its stand,  slowly round  a stationary bar magnet. 
92
DAVIS'S  MANUAL.
  145.  The  arrangement of iron filings around  the
poles  of a U-magnet,  as  represented  in  Fig.  48,
Fig. 48.
. .
                    depends upon  the directive ten-
                    dency  communicated  to  the
                    minute  particles.   As  will  be
                    explained  hereafter,  each par-
                    ticle of the filings becomes  a
                    temporary magnet, with a north
                    and  a  south  pole, while  at-
                    tached to the steel magnet.  The
                    filings are held together by their
                    mutual attractions,  and, having
                    thus great  freedom of  motion,
     •i'-   '.;;  V-v\\ readily obey the directive influ-
ence exerted upon them.
   146.  Spread a thin  covering of iron filings over a
sheet of paper, or thin pasteboard, and place a power-
ful U-magnet vertically beneath  it,  with the poles
close to the paper.  The dotted lines  in the cut (Fig.
49) show the arrangement which the  particles of iron
                           will assume.   Each one
                           becomes  a magnet with
                           two poles, and connects
                                 with   those  ad-
       J^^:^£|LSJjr>^' joining it, so as  to form
                           curved lines of a peculiar
                           character.  This experi-
                          ment may be performed
n a still more  satisfactory manner, by supporting the
paper,  with the magnet in contact  with  its under
surface, and then showering down iron sand or iron
Fig. 49.
 
MAGNETIC  CURVES.
93
filings  from  a sand-box held  some  inches above.
The particles of iron, as they strike the paper, can
thus more readily assume  the  positions to which
they tend under  the magnetic  influence.
  147.  The  lines formed by the filings afford a good
experimental  illustration of  what are called  magnetic
curves;  that  is,  the curves  into which  an  infinite
number of very minute magnetic needles suspended
freely  would  arrange  themselves,  if placed in  all
possible positions  about a magnet.   When  the par-
ticles are very small, the attractive force exerted  upon
them by  the magnet,  being the  difference of  its
action upon the two poles of each particle, is slight;
while the directive force is  very considerable.  The
direction assumed by each particle, and consequently
the  form of the magnetic curve,  connecting any point
on  one half  of the magnet  with the corresponding
point of the other half, is deducible, on mathematical
principles, from the laws of magnetic attraction and
repulsion.  The curvature of the lines is due to the
combined action of the two  poles of the magnet.  If
only one  pole acted on the  minute  particles,  they
would arrange themselves in straight lines, diverging
in all directions from  the pole, like  radii  from the
centre  of  a sphere.  This may be partially shown,
by placing a bar magnet perpendicularly under the
paper which  is strewed with filings, with  its upper
pole close to the  sheet. 
94
DAVIS'S  MANUAL.
II. IN REFERENCE TO A CURRENT OF ELECTRICITY.

   148.  It was discovered by Professor Oersted, of
Copenhagen, in the year  1819, that a magnet, freely
suspended, tends  to assume a  position at right angles
to the  direction of  a current  of electricity passing
near it.   This   may be shown by the  following
experiment: —
   149.  Let  N S (Fig. 50)  be a  magnetic  needle
poised  upon  a pivot  so as  to allow of a  free hori-
          fw 50.          zontal  motion,  and W R
W------jw»     -^______a  wire  passing  directly
        *'ov      ^'V-      over and parallel  to it.
   ° "     ^' ag^=    i jy   Of  course,  the  direction
                           of the wire must be north
                           and south, as the needle
                           will  necessarily  assume
                           that direction, by the in-
                           fluence of the earth.  If,
                           now, the  extremities of
                           the wire are put in con-
nection with the  poles of a galvanic battery, in such
a manner  as  to cause a current of electricity to pass
through it,  the  needle, N S, will  be deflected, and
will  turn  towards the position  a b  or c d,  according
to the  direction of the  current of positive electricity,
whether from W  to R, or from R to W.  If the wire
is placed in the same direction below the needle, the
deflections will be the  reverse of those  produced by
 
         deflection  of  needle.       95

the same current when flowing above.   If the posi-
tive  current  is  passing from south to north  in  the
wire, as shown by the arrow in  the cut, the north
pole  of  the  needle will  turn to   the  west if it be
below the  wire, and to the  east  if above it.
   150.  In these cases,  the  needle will  not  be  de-
flected so far as to assume a  position exactly at right
angles with the wire, on account of the influence of
the earth,  which still  acts  upon  the  magnet,  and
tends to draw it back to its original position.   It
will  accordingly come  to  rest in  a state of equilib-
rium  between  the  two  forces, in  a direction inter-
mediate  between a line at right angles  to the wire
and that of the  needle when controlled by the mag-
netism of  the earth alone.
   151.  The same  experiment may  be performed
with  the dipping needle, the wire  being  placed  par-
allel  with the needle.  By thus varying the positions
of the wire and the needle, it will be found that in all
cases the needle tends to place itself at right  angles
with the wire,  and to turn its north pole in a deter-
minate  direction with regard  to the wire.
   152.  The action  of  a conducting  wire  upon a
magnet exhibits, in one respect, a remarkable pecu-
liarity.   All  other known  forces   exerted  between
two points act in the  direction of a line joining these
points;  such is  the case with the  electric and mag-
netic  actions separately considered.  But the  electric
current exerts its magnetic influence laterally, at right
angles to  its own  course.   Nor does  the  magnetic
pole  move either directly towards or  directly from 
96
DAVIS'S  MANUAL.
the conducting wire, but tends to revolve around it
without  changing  its  distance.   Hence  the  force
must  be considered as acting in the direction  of a
tangent to  the circle  in which  the  magnetic  pole
would move.   It is true  that, in many positions of
the magnet with  regard to the wire, apparent attrac-
tions and repulsions occur ; but they are all referable
to a  force  acting  tangentially upon  the magnetic
poles, and  in a plane  perpendicular to the direction
of the current.  This peculiar action may be better
understood  by means of a figure.
   153.  Thus, let p n (Fig. 51)  be a wire, placed  in
a vertical position, and conveying a current down-
wards (p being connected with the positive pole of
       jv. 5jt          the battery.)   Now, suppose
7'
V
>
the north pole of a magnet,
N, to  be brought near  the
wire, and to be perpendicular
to any point  C.    If free to
move,  the pole will  revolve
              __j/^__. around C as a centre, in the
                       direction indicated by the ar-
                       rows in the cut; that is, in the
                       same direction as that of the
                       hands of a  watch,  when its
face is upwards.   The plane of the circle which the
pole describes is horizontal.  On causing the current
to ascend in the wire, the pole will rotate in the oppo-
site direction.  If the wire  is placed  in a horizontal
position, the plane in which the pole revolves  will,
of course, be vertical.  The actions of either a de- 
ASTATIC  needle.
97
scending  or an  ascending current upon the  south
pole are exactly the  reverse of those  exerted  on the
north pole.
   154.  In the experiment given in $  149, no revolu-
tion occurs,  because  the current, acting at once on
both  poles,  tends to  give them  motion in opposite
directions; so  that the  magnet comes to  rest in  a
position  of equilibrium  between these  two  forces,
across the wire.   It  will be shown hereafter  that  a
continued  rotation may be produced by  confining
the action to one pole.  If the wire  is movable and
the magnet fixed, the former will revolve around the
latter in a similar manner,  and  in the same directions.
Thus a wire conveying a descending, current  tends
to rotate  round  the  north pole of a  magnet,  in  the
direction  of  the  hands of a watch.
   155.  The two following articles of apparatus are
used to show  the directive tendency of a magnet
in reference  to  an electric current.
   156.  Astatic  Needle. — A magnetic needle, so
contrived  that its directive  tendency in respect to the
       Fi<r. 52.        earth is neutralized, so that it
       ^_^_^--===3»s  shall remain at rest in any  po-
n«—"   ""l\V^Z~~z=s=>lfi  sition, is called an astatic needle.
 sc^^-^r           It  is  constructed as represented
                     in  Fig. 52, consisting essentially
                     of  two needles,  one above  the
                     other, placed  in positions  the
                     reverse of each other in respect
                     to  their  poles.    Such a system
                     will  not  be affected  by  the
              9 
98
DA VIS'S  MANUAL.
magnetic influence of the earth, as whatever forces
may be  exerted  upon  the upper needle  will  be
counteracted by equal forces exerted  in reverse  di-
rections  upon  the  lower.  It  would  be  the same,
indeed, with the influence exerted  by the  current of
electricity,   if the wire could  be  placed  in  such a
position as to act  equally on both  needles.   But by
placing  the  wire  parallel to  and  above  the upper
needle, the  influence of  the wire  will  be far more
powerful upon the upper than upon the lower one,
and, the action of terrestrial magnetism being neu-
tralized,  the needle  will  assume a position  exactly
at right  angles with  the conducting  wire.   If  the
wire be  placed as nearly as  possible  between  the
needles,  and parallel  to  them, the influence  of  the
upper side of the wire will deflect the  upper needle
in the same direction as the  lower  needle  will be
deflected by the action of the lower side of the wire,
causing a more powerful effect.
   157.  Magnetic  Needle, half  brass. — In this
instrument  the steel needle is  wholly upon one side
of the point of support,  and  is counterpoised by  a
brass weight on the  other side.  By  this arrange-
ment, the  action of a current upon the pole which
is situated  at the  centre  of motion can have no in-
fluence in turning the magnet in any particular direc-
tion ; and  its motion will be  determined solely by
the  action  upon the other pole ;  no rotation, how-
ever, can  be obtained.   The object of  the instru-
ment is  to  show the directive tendency of  a single
pole with  reference to the electrical  current. 
                GALVANOMETERS.            99

   158.  Galvanometers. — If  the  wire transmitting
 (he electrical  current, after passing over the needle, is
 bent  and returned under it, as  in  Fig.  53, it might
                                   be supposed that,
                                   as the electricity
                                   which flows from
                                   C to  A  in  the
                                   upper part of the
                                   wire must pass in
                                   a contrary direc-
                                   tion, in returning
                                   from A to B, be-
                                   low  (the  cup  C
                                   being  connected
                                   with the positive
                                   pole of the bat-
tery, and B with  the negative), the influence of the
one part  of the  wire would neutralize that  of  the
other; for it  has already been stated  that  the needle
is deflected to one side or the other, according to the
direction of the electrical current.  And  this would
in fact be the case, if the returning part of the wire
were upon the same side of the  needle with the other
part, and at an  equal distance  from it.  But  a wire
transmitting an electrical current, when passing below
the needle, will  produce an effect the reverse  of that
produced by one passing above,  if the current in both
cases  flows in  the  same  direction.   Hence,  if  the
direction  of the  electric  current is  reversed  in  the
wire which passes below, it  will exert a force aux-
iliary, and not antagonist, to that of the wire passing
 
100
DAVIS'S  MANUAL.
above.   This is the case with  the arrangement here
represented.  The two  portions of the wire are not
allowed to touch each  other where they cross, but
are insulated at that point by some non-conductor of
electricity, as by  being  wound  with thread.   Instru-
ments  of  a variety of forms are  constructed  on the
above  principle, and are called galvanoscopes  or gal-
vanometers, as they serve to indicate the presence of a
current of electricity, and in some degree to measure
its quantity.
   159.  The  vertical portions  of the wire also aid
in deflecting  the needle ; as may be  shown by con-
necting both  the cups B and C with  cue pole of the
battery by two wires of equal  length  and thickness,
and the cup A with the  other pole (say the  positive).
The current  will then  be  divided  into two portions
very nearly equal, both  flowing in the same  direction,
and at the same distance from the  magnet,  M, but
one below and  the  other  above it.   Now,  if the
horizontal  portions  of  the  wire  alone  acted  on the
needle, it  would remain unaffected;  but it  will be
found to be deflected to a considerable extent by the
current which  is descending in  the  vertical  portion
of the wire near A, and ascending in that  below B,
as these conspire in  their  influence.
   160.  Horizontal  Galvanometer. — If  the wire
is carried many times around the needle, as  in Fig.
54, the power of the instrument is  much increased,
as each turn of the wire adds its  influence ; provided
the wire is not so long,  or of so small a size, as to be
unable to  convey the whole of  the current.   The 
         UPRIGHT  GALVANOMETER.     101

instrument thus becomes a delicate test  of the pres-
ence of a current of electricity.  The coil of wire is
supported on a  tripod stand, with levelling screws;
the ends, C and  D, of the wires being connected with
the screw cups, A and B.
     Fig. 55.        161.  Upright Galvanometer.—
                In  this  instrument,  represented in
                Fig.  55, both the coil of wire and
                the  needle  are  placed in a vertical
                position, the north pole being made
                a  little heavier, in  order  to keep
                the  magnet  perpendicular.   When
                a  current  is  passed  through  the
                coil,  the  deflection  is towards a
                horizontal  position.   The needle is
                made of large  size, for the purpose
                of exhibiting the deflections  before
                an audience.
             9*
 
102
LATIS'S  MANUAL.
   162.   Galvanometer with Astatic  Needle. —
This instrument is represented in Fig. 39, in connec-
tion with a thermo-electric pair.  It is constructed on
a small scale, in order to be delicate ; and the needle
is  nearly astatic.    The  slight  degree  of directive
tendency which  the  needle  is allowed  to retain
becomes the measure  of  the force of  the  electric
current, as the angle of deflection from the north and
south line shows how far this resistance is overcome.
This instrument may be made so extremely delicate
in its indications,  that,  if two  fine wires, one of cop-
per and one of  zinc, are connected with  it. and their
ends slightly immersed in  diluted  acid,  or even in
water,  it will be  very  perceptibly affected.   Before
proceeding to  experiment  with any  galvanometer,
it should be so  placed  that the direction of the coil
may coincide  with  that  of the  needle, as this  is
the position of greatest sensibility.
   163.  The galvanometer  is  a measurer of what is
called the quantity of electricity, but takes no cog-
nizance of intensity.   Mechanical electricity,  which
possesses great  intensity and but little quantity, very
slightly  deflects  the needle  of the galvanometer.
The current  from one  galvanic pair influences the
needle powerfully, the quantity being very great, and
the intensity small.   If a hundred pairs be connected
together  in a single series, the intensity is increased
a hundred fold ; but the quantity remains the same,
and  the needle is  but little  more deflected than  by
one  pair.   The reason that there  is any difference
in this respect  is,  that, when the  electricity is of 
           rotation  of  magnet.        103

high tension, the wire of the galvanometer obstructs
the current less, and more actually passes through it.
   164.  In thermo-electricity, with a single pair, the
intensity is less in proportion to the quantity than
with a single galvanic pair, and the current is strongly
indicated  by the  galvanometer.   The  amount  of
decomposing power  in  a current  of  electricity  is
always  exactly as its  quantity.   The  galvanometer
indicates, therefore, the electro-magnetic and the de-
composing capacity of a current  of electricity.  An
intense electrical current  decomposes more easily than
one  of  little intensity;  but  the  amount of matter
decomposed is  proportional merely to  the quantity
of the current.   Besides the  galvanometers in which
a  magnetic  needle is used,  other instruments for
measuring  the quantity of  an  electric current will be
described  farther on.
   165.  When  a wire conveying a current of  elec-
tricity is brought near to a magnetic pole, the pole
tends to revolve around  it, as has been  explained in
$ 153. If the current  acts equally upon both poles, no
rotation occurs,  because  they  tend to move in oppo-
site directions;  and the magnet rests across the wire
in a position of equilibrium between the two forces.
But  if the  action of  the current "is. limited to one
pole (which was first  effected  by Professor Faraday),
a continued revolution is produced.   If the magnet
has  liberty of  motion,  it will  revolve  around the
wire • if the wire  only is free to move,  it will rotate
around the pole.  When both the wire and the mag-
net are  at  liberty to  move, they will revolve in the 
104
davis's  manual..
same  direction  round a common  centre of  motion.
A  number  of instruments  have been  contrived for
exhibiting  these movements.
   166.  Magnet  revolving  round  a Conducting
Wire.—In the instrument represented in  Fig. 56,
       Fi<r. 50.       the magnet, N S, has  a double
                    bend in  the middle, so that this
                    part  is  horizontal,  while  the
                    extremities are  vertical.   To
                    its north pole, N, is attached a
                    piece of brass  at a right angle,
                    bearing  a pivot,  which rests in
                    an agate cup fixed on the stand.
                    A wire  loop,  attached  to the
                    upper pole, S,  encircles a verti-
                    cal  wire fixed in the axis  of
                    motion,  and  thus  keeps the
                    magnet upright.  The galvanic
                    current  is  conveyed  by this
                    vertical  wire :  it is surmounted
                    by a brass cup, A, and its lower
                    end dips into a  small mercury
                    cup  on  the  horizontal  portion
of the magnet.   From this part projects a bent  wire,
which dips into a circular  cistern of  mercury,  open
in the centre, to  allow the magnet  to pass through,
and  supported  independently  of it.   A wire, termi-
nated  by  a brass cup, B,  for connection  with the
battery, proceeds  outwardly from  the  cistern.   This
arrangement allows the current to flow down by the
side of the upper  pole of the magnet, until it reaches
 
REVOLVING  MAGNET.
105
its middle, whence it is conveyed off in such a direc-
tion as not to act upon the lower pole.   On making
connection with  the battery, the  magnet will revolve
rapidly around the wire ;  the direction of the rotation
depending upon  that  of  the current.
   167.  Magnet  revolving  on its  Axis. — The  in-
strument represented  in Fig. 57  is designed to show
           Fig. 57.              that the  action  be-
                               tween  the current
                               and   the  magnet
                               takes  place  equal-
                               ly  well  when   the
                               magnet itself forms
                               the  conductor   of
                               the electricity.  The
                               lower end, N, of the
                               magnet, being point-
                               ed, is supported on
                               an agate  at the  bot-
                               tom of a brass cup,
                               connected under the
base-board with  the screw-cup C.  The  upper end,
S, is  hollowed out to receive the  end of the wire
fixed  to the  cup A;  the  brass arm supporting  this
cup is insulated  from the brass pillar  by some non-
conductor  of  electricity.   To  the middle of  the
magnet is fixed  a small ivory cistern, for  containing
mercury, into which dips the end of a wire, connected
.vith the cup B.  Thus the magnet is supported with
its north pole downwards, and is free to rotate round
its vertical axis.  A little mercury should  be put into
the cavity at S, and into the brass cup at  N, and the
 
106           DAVIS'S  MANUAL.
ivory cistern be filled sufficiently to establish a con-
nection  between  the  magnet  and the wire attached
to B.  When  the cups A and B  are  connected with
the battery, the current will flow through the upper
half of the magnet, causing it to rotate rapidly.  If
the cups B and C form  the connection, the  current
will traverse the  lower half, equally producing  revo-
lution of the  magnet.  Now, connect A and C with
the battery, and  no motion will result, because the
electricity passes through the whole length of the mag-
net in such a  manner that the tendency of one pole
to rotate is counteracted by that of  the other to move
in the  opposite direction.  Connect B with one pole
of the battery, and A and C both with the other pole,
The magnet will now revolve ; since the current  as-
cends in one half of its length and descends in the other.
                          168.   Revolving   Wire
                        Frame. — The revolution of
                        a conductor  round a magnet
                        is shown by the instrument
                        represented in Fig. 58.  Two
                        light  frames of copper  wire.
                        R R, are supported by pivots
                        resting  on the  poles, N and
S.
of a steel magnet of the
U form ; a  small  cavity be-
ing drilled  in each  pole to
receive an agate for the bear-
ing of the pivot.   The lower
extremities  of the wires dip
into mercury  contained  in
two circular cisterns sliding 
           REVOLVING  CYLINDER.        107

on the arms of the magnet.   Bent wires, passing from
the interior of the cells, support the cups A and  D;
and the  cisterns  themselves are fixed at any required
height by means of binding screws attached to them.
Each of the wire frames is surmounted by a mercury
cup; into these dip the wires projecting downwards
from the cups B and C.
   169.  The cisterns being partly filled with mercury,
fix them at  such a height that the lower extremities
of the wire frames may just touch its surface.  The
cups surmounting  the frames should also  contain a
little mercury.   When the cups A and B are con-
nected with the  battery,  the left-hand frame will re-
volve, in consequence of the action of the north pole
of the magnet upon the current flowing in the vertical
portions of the frame.   By  uniting C and D with the
battery,  the other frame will rotate.   On transmitting
the current from  A to D, it  will ascend in one frame,
and, passing along the brass arm which supports B and
C, will descend in the other, causing  them both  to
revolve in the same direction.  Instead of the frame,
a single  wire may be employed, having the form of a
loose  helix surrounding  the pole, its convolutions
being a quarter  of an  inch or more  apart.
   170.  Revolving Cylinder. — This instrument is
on the same  principle  as  that last described, and  the
motion takes place in the  same manner;  the only
difference being that two light copper cylinders, c c,
Fiar. 59, are substituted for the wire frames.   These
cylinders are  serrated at their lower edge,  as  shown
in the figure, to lessen the  friction which they expe- 
 108           DAVIS'S  MANUAL.

 rience in moving through the mercury.   The cups
 for battery connections are lettered in correspondence
                      with  those in  the preceding
                      cut.  (Fig. 58.)
                         171.  In the case of a con-
                      ducting wire  revolving  round
                      a  magnet,  the  circumstance
                      of the two being  joined to-
                      gether does not  affect the re-
                      sult, the wire moving  with
                      sufficient power to cause the
                      magnet to  turn  on  its axis
                      with   considerable  rapidity,
                      when delicately supported :  a
                      bar magnet is of  course em-
                      ployed.  A figure and descrip-
                      tion of an instrument designed
                      to show this  revolution will
 be found in Silliman's Journal, Vol. XL. p. 111.
   172.  The current  passing within the voltaic bat-
 tery itself  exhibits the   same electro-magnetic prop-
 erties that  it does while flowing along a  conducting
 wire connecting  the  poles.   Hence  the  battery, if
 made small and light, will revolve by  the influence
 of a  magnet.   This  is  effected  in the following
 manner.
   173.  Rotating Battery.—A small double cylin-
 der of copper, closed at the bottom, is supported upon
 the pole  of a magnet, by means of an arch of copper
 passing  across the inner  cylinder, and having a pivot
projecting downwards from  its under surface, which
 
rotating   battery.
109
rests in an agate cup on the pole.  The inner cylin-
der of  course has no bottom.   A cylinder of zinc is
                  supported by a pivot in a similar
                  manner  upon the  copper arch,
                  and,  being intermediate in  size
                  between the two copper  cylin-
                  ders, hangs  freely  in  the cell.
                  This  arrangement  allows  each
                  plate to revolve independently of
                  the  other.   In Fig. 60 two  bat-
                  teries are represented, one on each
                  pole of a U-magnet, the  one on
                  the  south  pole  being shown  in
                  section; in  this  the zinc  plate
                  z is seen  suspended  within the
                  copper  vessel.
                     174.  On  introducing  diluted
acid into the copper  vessel, an electric current imme-
diately begins  to  circulate,  which  passes from the
zinc to the copper through the acid, and, ascending
from the copper through the arch, descends again to
the zinc.  Hence the zinc  plate is in  the condition of
a conductor conveying  a stream of electricity down-
wards, and will consequently revolve under the influ-
ence of the pole which it surrounds.   The  copper
cylinder,  on the contrary, is  in the  situation  of a
conductor  conveying  a current  upwards, and  will
rotate  in  the  opposite  direction.  When there is a
battery on  each  pole  of a U-magnet,  the two  cop-
per vessels  will be  seen to  revolve  in contrary di-
rections, and  the two  zinc  cylinders in  directions
               10
 
110
DAVIS'S  MANUAL.
opposite  to these,  and of  course  also  contrary to
each other.
   175.  Vibrating  Wire. — A copper wire, seen at
W, in Fig. 61, is suspended over a small basin for con-
                              taining mercury  ex-
                              cavated in  the  stand,
                              by  means  of a brass
                              arm supporting a mer-
                              cury  cup,  in  which
                              the upper end  of the
                              wire rests: this mode
                              of suspension  allows
                              it to  vibrate  freely,
                              if its upper  end is
                              properly bent.  Two
                              cups  for connection
                              with the battery com-
municate, one with the mercury in  the excavation,
the other with  the cup which sustains the wire.
   176.  The basin  being  supplied with a sufficient
quantity of mercury to cover the  lower end  of the
suspended  wire,  lay a horseshoe magnet  in a hori-
zontal position on  the stand,  with  one of  its legs on
each  side  of the  wire.   When communication  is
established with the battery, the  poles of the magnet
will conspire  in urging the wire  either backwards or
forwards between them, according  to the direction in
which the current  flows through it, and the position
of the  magnetic poles.   In either case, the motion
will carry it  out of the mercury  into  the position
shown by the dotted lines in the cut; and the circuit
 
VIBRATING   WIRE.
Ill
being thus broken, the wire will fall back by its own
weight;  when,  the current being  reestablished,  it
will again quit the mercury, as before,  and a rapid
vibration  will be produced.  The vibration may be
made somewhat more active by raising the magnet a
little from the stand, and  nearly to the height of the
middle of the wire.
   177.  The instrument represented in Fig. 62 differs
from  the  one last described in the mode of suspen-
       Fig- 62.       sion  of the wire and the verti-
                    cal position of the magnet.  The
                    wire is fixed to a little cylinder,
                    moving freely  on  a horizontal
                    axis,  which  is supported by a
                    brass pillar,  secured upon  one
                    of the magnetic poles.   A small
                    mercury  trough,  supported  be-
                    tween  the legs  of  the magnet,
                    is  connected, under the stand,
                    with  one of  the  screw-cups.
                    Thus the current is  conveyed
                    to the mercury.  The other  cup
                    is  connected  with  the magnet,
and, through the pillar, with  the  wire,  W.
   178. A  single magnetic  pole, placed either in a
horizontal or vertical position, by the side of a wire
suspended  as in  the last two figures,  will cause  it to
vibrate; but  its  motion is less active  than with two.
The tendency of  the  wire is  to  revolve round  the
pole presented to it, as has been explained in $ 154;
and, when  suspended  between a  north and  south
pole, simultaneously around both.
 
112
DAVIS'S  MANUAL.
  179.  Gold  Leaf Galvanoscope. — In this instru-
ment, represented  in  Fig. 63, a narrow slip of gold
      Fig. 63.      leaf, G, is suspended between the
                  poles of a U-magnet.   The legs
                  of the magnet are brought near
                  to each  other,  in order to render
                  their action on the current con-
                  veyed  by  the gold  leaf  more
                  powerful, and also to allow  of the
                  whole arrangement being enclos-
                  ed in a wide glass tube, T.  This
                  prevents the interference of cur-
                  rents of air, and secures the gold
                  leaf from injury.  The  upper end
                  of the slip  is in metallic connec-
                  tion  with  the  screw  cup sur-
                  mounting  the tube.   Its  lower
                  end   communicates   with   the
                  screw cup on the stand.  When
                  a  very  feeble current of  elec-
tricity is  transmitted through the gold leaf,  it be-
comes curved forwards or backwards,  according  to
the course of the  current; in either case,  tending to
move away from  between  the magnetic  poles in a
lateral direction.   The  motion depends on the same
cause as that of the wire in the instrument described
in $ 177.   This  instrument does not  indicate  the
quantity of the electrical current, but  is an exceed-
ingly delicate  test  of  its existence and direction.  A
powerful current would of  course destroy the gold
leaf.
  180.  Revolving Spur-Wheel.—The  reciprocat-
WIIIIITMB
 
REVOLVING  SPUR-WHEEL.       113
ing movement in the  instrument described in $ 177
may be converted into one  of rotation, by  making
Fig. 64.
                        use of a copper wheel, the
                        circumference  of which is
                        cut into rays, instead of the
                        wire.   The  points  of the
                        wheel, W (Fig. 64,) dip in-
                        to mercury contained  in a
                        small trough, T, supported
                        between the legs of a U-
                        magnet, fixed in an upright
                        position.   The axis  of the
                        wheel is supported by two
                        brass pillars upon the poles,
                        N and  S,  of  the magnet.
                        One of the screw-cups on
                        the stand is connected with
                        the  magnet,  and  through
that  with the wheel.   The  mercury trough,  which
is insulated from the magnet, is connected with  the
other cup.
  181. When connection is made with  the battery,
the current passes from the axis of the wheel to  the
trough through any one of the points which happens
to touch  the  mercury.   Under these circumstances,
the ray through which  the current  is flowing passes
forward between the poles of the  magnet, like  the
vibrating wire in Fig.  62, until it  rises out  of the
mercury.   At this  moment the next succeeding  ray
enters  it,  and goes through the same process; and
so on.
             10*
 
114
DAVIS'S  MANUAL.
  182.  If the quantity of mercury is so adjusted that
one ray shall quit its surface before the succeeding one
touches it, a spark will  be seen  at each  rupture of
contact.  When the machine is set in  motion in the
dark, so that  it may be illuminated  by the rapid suc-
cession of these sparks, the  revolving  wheel  will
appear to be nearly at rest;  exhibiting only a quick
vibratory  movement, in consequence  of  the sparks
not succeeding each other precisely at the same point.
This optical  illusion arises  from the  fact,  that the
electric light  is so extremely  transient in its duration,
that the wheel has not  time  to move  to  any appre-
ciable  extent during  the  electrical discharge; and
therefore each  spark  shows  it in an apparently sta-
tionary position.  If the sparks occur at one place
more frequently than at  the rate of  eight in a second
of time, the  eye cannot appreciate  them  separately,
and the impression  of a  continuous  light is  received.
For this reason, the wheel is  seen constantly, as if it
were illuminated by  a  steady light,  instead of an
intermitting  one.
  183.  A more rapid revolution will be obtained  if
a small  electro-magnet  be substituted for  the steel
magnet.   The electro-magnet is included in the cir-
cuit with the spur-wheel, so that the  current flows
through them in succession.   Here the direction of
the rotation will not be changed by reversing that of
the current, since the polarity of the electro-magnet
is also reversed.
  _~4.  Revolving  Disc — It is  not essential  to
divide the wheel into rays,  in  order to obtain rota- 
             DE  LA  RIVE'S  RING.          115

tion.  A circular metallic  disc will revolve equally
well between the poles of a magnet.  In this  case,
the electric circuit remains  uninterrupted during the
entire  revolution,  and  no  sparks  appear,  as  with
the spur-wheel.
   185.  De la Rive's Ring. — A coil of wire, while
transmitting the  electric current, exhibits the same
reactions with a magnet as the straight wire in Figs.
                                 61 and 62; but the
                                 circular  direction
                                 in which  the cur-
                                 rent flows gives to
                                 the coil an  appa-
                                 rent  magnetic po-
                                 larity.   This fact
                                 may  be shown by
                                 means of the appa-
                                 ratus figured in the
                                 adjoining cut.  One
                                 end  of  the  wire
                                 forming  the  coil,
                                 or helix, C, is sol-
dered to a very small plate of copper, c, and the other
to a similar plate of zinc, z.   These plates  are fast
ened to a small piece of  wood, in order to keep them
apart, and  placed in a little glass cup, D.   To  put
the instrument  in   action,  a  sufficient quantity of
water, acidulated  by  a few drops of sulphuric  or
nitric acid, is poured into the  glass cup to cover the
plates, and  the whole apparatus is floated  in  a basin
of water.   The coil will now be found to place itself
with its axis north  and south, being influenced by
 
116
DAVIS'S  MANUAL.
the polarity of the earth, like a compass needle.   The
arrow indicates the course of the  galvanic current in
the coil from the copper to the zinc.
   186.  Take a bar magnet, M, and, holding it hori-
zontally, bring its north  pole near to the south pole
of the ring.   The ring will move towards  the mag-
net, and pass over it until it reaches its middle, where
it will rest  in a state of equilibrium; returning to this
position, if moved towards either  pole and  then  left
at  liberty.   Now, holding the ring in  its  position,
withdraw  the  magnet,  and pass it  again  half way
through  the  coil, but with its poles  reversed.  The
ring, when set at liberty, will, unless placed exactly
at  the  centre, move towards the pole which is near-
est, and, passing  on till clear  of the magnet, will
turn round and present its other face.   It will then
be attracted,  and pass again over the pole till it rests
in  equilibrium at the  middle of the magnet.
                                         187.   Vi-
                                      brating Coil
                                      Engine.— In
                                      the   instru-
                                      ment  repre-
                                      sented    in
                                      Fig. 66, two
                                      heliacal coils
                                      are   so   sus-
                                      pended  from
                                      an   arm  at-
                                      tached to  the
                                      tall brass pil-
                                      lar as  to  al-
 
         VIBRATING  COIL  ENGINE.      117

low of their moving to some distance over the poles,
N and  S, of a steel magnet.  When uninfluenced by
the electric current,  the  coils hang vertically from
their points of support.   There are two  cranks on
the axis of the balance-wheel above the magnet, which
convert the vibration of the coils  into revolution.
On opposite sides of  the  axis are two wires,  tipped
with silver springs ; each  of these is connected under
the base-board with one end of the wire forming each
coil.   At the point where the springs press, a part of
the axis is  cut  away, leaving a third or  a quarter of
the cylindrical  surface prominent;  over this  is sol-
dered a thin slip of silver.   The effect of this arrange-
ment,  which is  called a  break-piece, is,  that each
spring  alternately transmits the electric current from
the axis to its coil during a part of the revolution of
the wheel, while pressing upon the cylindrical  por-
tion of the  axis.  The screw-cups are connected, one
with the axis of the  wheel, the other with  one end
of the wire of both  coils.
   188.  Connection being made with a galvanic bat-
tery, the  current  traverses one of  the  coils,  which
then moves  over the pole which it  surrounds, to-
wards the middle of the magnet, in the same manner
as De la Rive's ring.  When  it  has  passed some
distance, the motion  produced in the balance-wheel
interrupts  the  current  by breaking the contact be-
tween  the  cylindrical part of the axis and the spring,
and the  coil falls back to its first position.   As the
wheel  moves on, the  other spring comes  in contact
with the axis, causing the  other coil  to be charged,
and to go  through the  same movements.  The  coils 
118           DAVIS'S  MANUAL.

thus vibrate alternately, producing a rapid rotation
of the  balance-wheel.
   189.  Reciprocating Coil Engine. —Fig. 67 rep-
resents an instrument in which two coils, C C, mount-
                     Fig. 67.
ed upon wheels, pass over the legs of a steel magnet
fixed  in  a horizontal position, the  wheels moving
upon  inclined rails.   When  the  instrument is con-
nected with  the battery, the coils become charged,
and move  along the  poles towards  the bend of the
magnet.   The battery connections must be so made
that the current shall  pass in the  proper direction, or
the coils will tend to move away from the magnet
rather than over it.   When the coils reach the  bend
of the magnet, the  platform  upon  which they are
secured comes in contact  with  the wire-spring, A,
and,  by the movement  produced in that, breaks the
contact at B.  The  current being  interrupted, the
coils slide  down  the rails  by the  force  of gravity,
until the  platform reaches  a pin on  the rod near B,
whose movement renews the contact.
   190.  Reciprocating  Magnet  Engine. — Fig. 68 
REVOLVING  COIL.
119
represents an instrument on the same principle as the
last, except that the coils are stationary and the mag-
                      Fig. 68.
net moves within them.   It is supported by wheels
moving upon the inclined rails.  Wlien the bend of
the magnet reaches the coils, the axle of the wheels near
B strikes a spring, and breaks contact at B, by pushing
along a little  rod  below the wheels.   As the magnet
falls back by gravity, the axle touches another spring
on the same rod, drawing it along until a pin upon the
rod strikes the pillar at  B, and renews the circuit.
Fig. 69.
  191.  Revolving  Coil. — This
instrument consists of  a U-magnet
fixed  upon  a stand, in a vertical
position, and a circular coil of in-
sulated copper wire, C  (Fig. 69), so
arranged as to revolve on a vertical
axis between the magnetic  poles.
The rotation is effected in a differ-
ent manner  from any previously
mentioned.   The polarity  of the
coil is reversed twice in each revo-
lution, by means of the pole-changer,
invented  by Dr.  Page,  which is
employed in many  of the instru-
ments to be hereafter described. 
120
DAVIS'S  MANUAL.
The pole-changer attached  to the  coil is seen at P,
and a horizontal section of it is shown in  Fig. 70.
     Fig. 70.       It consists of two small semi-cylin-
     ^     ___--  drical pieces of silver, s s, fixed on
      s(^)s        opposite sides of the axis of motion,
-----             A, but insulated from that and from
each other ;  to each of these segments is soldered one
end of the wire composing the coil.   The  battery
current is conveyed to the coil by means  of  two
wires terminated by horizontal  portions of flattened
silver wire, W W, which press  slightly on opposite
sides of the pole-changer, and must be so arranged
that the direction of the current in the coil may be
reversed at the moment when its axis is passing be-
tween  the poles of the magnet.
   192.  The coil  being placed with  its axis at right
angles to the plane of the  poles,  and connection made
with a battery, one extremity of the axis, or, in other
words, one face of the coil, acquires north polarity,
and the other  south  polarity, in the same manner as
De la Rive's ring.  The  action  of the  magnet now
causes it to move round a quarter  of a circle in one
direction or the  other,  according to the course of the
current, so as to bring  its  poles between those of the
magnet.   In this position it would  remain,  were it
not that, as soon as it reaches  it, the pole-changer,
which is  carried  round with it, presents each of its
segments to that  stationary  silver  spring which  was
before in contact with the opposite segment.   By
this movement,  the  current  in the coil  is first inter-
rupted for a moment, and,  as the coil passes on, is
immediately renewed in the contrary direction, thus 
REVOLVING  rectangle.        121
reversing  the  polarity.   Each end of the axis being
now repelled by the magnetic pole which previously
attracted it, the coil turns half way round, so as  to
present its opposite faces to the poles.  At this point,
the direction of the current is again reversed, causing
the motion  to be continued  in the  same direction;
thus producing a rapid  revolution.   Instead of a coil
of large diameter, the wire may be coiled into a long
helix of small diameter, which  will  rotate in the
same manner.
   193.  Revolving  Rectangle. — This instrument
is  similar in principle to the last described, a rect-
          Fig.  71.          angular coil  of  wire,  C
                         (Fig. 71), being substitut-
                         ed for the ring.  The rota-
                         tion is much more rapid in
                         consequence of  the prox-
                         imity  of the rectangle  to
                         the magnet, not only near
                         its poles,  but  throughout
                         the greater  part  of  its
                         length.   By this means.
                         the great speed of eight  or
                         ten thousand  revolutions
                         in  a minute may be  at-
                         tained.   In the  cut, the
                         two silver springs, which
                         press on the pole-changer,
                         are seen at a, each of them
                         attached  to  a  stout  brass
wire, proceeding  from  one  of the cups  for battery
              11
 
122           davis's  manual.
connection ; these wires pass through the brass arch
surmounting the U-magnet, but are insulated from it.
  194.  Revolving  Galvanometer Needle.—Fig.
72 represents an instrument  of similar construction
                   to  the  Upright Galvanometer
     Fie? 72.
                   (Fig.  55), except  that a con-
                   tinued revolution  of  the  mag-
                   netic needle is obtained by  the
                   following arrangement: One end
                   of  the wire  composing the coil
                   connects with one  of the screw-
                   cups on  the stand,  and its other
                   end with  the bearings of  the
                   shaft on which  the  needle  re-
                   volves.  On the shaft is a break-
                   piece, seen at B,  in  the  front
                   view of  the  needle, given sepa-
                   rately in the cut, upon which  a
wire, W, connected with the  other screw-cup, presses
during half of the revolution.  The instrument may
be used as a  galvanometer, by  removing W from the
break-piece, and bringing it into contact with a silver
pin, not shown in the cut,  which connects it directly
with the coil, without the  intervention  of the break-
piece.   If the direction  of the  battery current  is re-
versed, the needle  revolves in the opposite direction.
  195.  Revolving Coil  and Magnet.  — In this in-
strument, represented in Fig. 73, a circular coil of
wire, C, is fitted to revolve, on a vertical  axis, between
the poles of two steel magnets.  So far it resembles
in principle the Revolving Coil  (Fig.  69);  but in
 
REVOLVING  COIL   AND  MAGNET.   123
this instance the magnets rotate also.   For this  pur-
pose, they are made of thin steel, and bent into a semi-
Fig. 73.
                            circular form.  The two
                            are  connected by strips
                            of brass, so as to form a
                            circle,  the similar poles
                            being  near  each other,
                            as indicated by  the let-
                            ters  in  the  cut.  This
                            circle is a little larger
                            than the  coil,  and  re-
                            volves  freely  round  it
                            on  a vertical  axis.   A
                            peculiar arrangement  is
                            required, in   order   to
transmit the  battery current to the  pole-changer be-
longing to the  coil.   The springs which press upon
it  are connected with two  small cylinders of silver,
surrounding the  shaft of the magnet and  insulated
from it, one  being a little  below the other;  or the
cylindrical shaft  itself may answer  for one of them.
The wires proceeding from the  screw-cups on the
stand press upon  these  cylinders.  In  this  manner
the current is conveyed to the springs bearing upon
the pole-changer in  a constant  direction,  notwith-
standing that they are carried round with the magnet
in  its revolutions.  When connection is made with
the battery, the mutual  action between the coil and
the magnet causes them both to revolve, but in con-
trary directions ; on the well-known mechanical prin-
ciple, that action and  reaction  are always equal and 
124
D A V I S ' S  MANUAL.
opposite  to each  other.  On changing the direction
of the galvanic  current, both the wire coil and  the
magnets  revolve  in the  opposite direction.
   196.  Thermo-Electric  Revolving   Arch. — It
                        has been shown that when
                        a   galvanic   current flows
                        through a helix, such as De
                        la Rive's ring, $ 185, its faces
                        acquire  polarity, and, if free
                        to move, arrange themselves
                        north  and  south.   In Fig.
                        74 there is a  stand, support-
                        ing an  upright  brass  pillar
                        with  an agate  cup at  the
                        top.   On this  is balanced
                        by a pivot, at A, av. arch of
"OP—               yp  brass wire,  the two  ends of
which are connected by a German silver wire  en-
circling the pillar.
   197.  If the stand  be arranged according. to  the
points of the compass, and one  of the junctions of the
brass  and German silver be heated  by a spirit lamp
on the east side of the stand at  E, a thermo-electric
current will be set in  motion from the German silver,
through the heated junction, to the  brass, and back,
through the arch, to the German silver.   The current,
thus established, gives polarity  to the  faces  of  the
arch,  as  if it  were a coil  or  helix;  circulating  in
such  a direction, that the  face,  which is turned to-
wards the north, exhibits south polarity.   Since  the
magnetic  pole of the earth there situated  is itself a
Fig. 74.
238948234823482353314853484853 
       thermo-electric  rotations.   125

  south pole, similar poles are presented  towards each
  other, and the arch is obliged  to make a semi-revolu-
  tion on its axis,  in order to present its  northern face
  to this  pole.   This  movement brings the other junc-
  tion into the flame, and a current is produced opposite
  to the former one, which changes  the polarity of the
  arch, and obliges it to move on through  another semi-
  revolution.    Thus  the  currents  are  reversed, and
  slow rotation  ensues.   This is  probably the most
  delicate reaction  between the magnetism of the earth
  and a current of  electricity which  has been observed.
    198. If the lamp  be  put to the south of east, the
  heated  junction of the arch will move  round by the
  south;  if it  be put to the  north of east, the heated
  junction will  move  round  by the north ; just  as a
  compass needle,  if  its north pole is  made to point
  south,  returns to its natural position either by  the
  east or  west, if it is inclined to the one  or the other.
  If the spirit lamp be  placed exactly west, or  at W in
  the figure, the current which is excited  tends to keep
  the  arch stationary,  by causing the face which  ex-
  hibits north  polarity to be directed towards the south
  magnetic pole of  the earth.
    199.  Thermo-Electric  Revolving  Arch on  U-
  Magnet.—If a  thermo-electric arch A B (Fig. 75),
  similar  to the one just described, be balanced on one
  of the poles of a  U-magnet, the reaction between the
  polarity induced  in it, by heating one of its junctions,
- and  the magnetism  of the  opposite pole of  the mag-
  net,  will be  much more energetic  than  in the former
  case with the  earth.  It resembles, in  principle, the
               11* 
126            davis's  MANUAL.

Revolving Coil, $ 191, except that it is attracted  and
repelled by a single pole instead of two, the pole  on
                   which  it is supported having  no
                   influence  upon it.  In  this  and
                   other instruments of  the same
                   kind, the upper part of the arch
                   may, with equal  advantage,  be
                   of silver instead of brass.
                     200.  The  most favorable po-
                   sition for the lamp  is  not that
                   represented in the figure, but at
                   a right angle with the  line con-
                   necting the two  poles, and in a
                   line  with the pole on which the
                   frame is  mounted ; or in a situa-
                   tion  analogous to the  east side
                   of the  stand  of the  last-describ-
                   ed instrument.   By  varying the
                   lamp to one side  or the other of
this  position,  the  arch will  revolve in either  direc-
tion, as before.   On the opposite side of the pole, the
lamp would have no tendency to  produce revolution;
though, if the arch were  mounted on the south pole,
the lamp should be on the farther side  of  the mag-
net, and in a line with  that pole, in order to cause
rotation.
  201. Thermo-Electric  Revolving Wire Frames.
— This instrument,  represented  in Fig. 76, consists
of two frames mounted upon the poles of a U-magnet.
These frames are formed  of two  arches,  or rather
rectangles,  similar  in construction  to  that  in  the
 
thermo-electric  arch.      127
instrument last  described, crossing each other at right
angles;  and they act on the same  principle  as that,
Pig. 76.
                the second rectangle only contrib-
                uting to the rotation produced by
              s the first.   In each individual rect-
                angle the current is reversed every
           -^~q half revolution.   These are gen-
                erally made of silver and platinum ;
                but German silver, in combination
                with  brass  or  silver,  occasions a
                stronger current.  The lnwer hori-
                zontal portions of the frames, mark-
                ed G G in the cut,  are composed
                of German  silver, and the  other
                parts,  s  s, of  silver.  A  frame
                is usually mounted on each  pole;
                the attractions  and  repulsions  of
each frame proceeding altogether  from the  opposite
pole.  In order to  heat the  junctions of both frames
at once, the lamp  is placed between  the  two poles,
by which there is  a loss of attraction  and repulsion
to each frame through the distance of 90°, in which
the heat would act, if two lamps were employed at
right angles to the line  of junction of the poles.
  202. Thermo-Electric Arch rotating between
the Poles of a  U-Magnet.—Fig. 77 represents a
thermo-electric  arch,  mounted upon a brass pillar,
between  the  poles of a  horseshoe  magnet; the  cir-
cular part is of German silver, and the upper part of
silver.  In  this case, both poles conspire in producing
revolution,  the motion of  the arch  depending upon
 
128
DAVIS'S  MANUAL.
the same principle as that of the  Revolving  Coil.
Yet the  different  mode  of  reversing  the current
                  in  this  instrument occasions the
                  arch to rotate  in  either direction
                  when the lamp is in  front of the
                  magnet,  and  to   remain at  rest
                  when the  lamp  is en the other
                  side.  A stand to support the lamp
                  slides on the  brass pillar, and  is
                  fixed  at any required  height by
                  means of a binding  screw.   The
                  lamp should be placed in the po-
                  sition  represented in  the cut, in
                  front of the magnet, its north pole
                  being on the left.
                    203.  When either of the junc-
                  tions is in the flame, a current flows
                  from  the  German silver  to  the
                  silver,  ascending  by  the  heated
side of the arch, and descending by the other.  That
face which  is presented towards the north pole ac-
quires north polarity, and  the  other face  south  polar-
ity.  The influence of the magnet  now causes the
arch to  turn  half  way  round, so as to present its
southern face  to  the  north pole.    This movement
brings  the other  junction  into the  flame ;  the  po-
larity of the arch  is reversed, and  it moves  on as
before.
  204.  If the lamp be placed in  the corresponding
position on  the other side  of  the magnet, the  direc-
tion of  the  current will be  such  that the southern
 
        DOUBLE  REVOLVING  ARCH.      129

face of the arch will be presented towards the north
pole.   In  this position the arch  tends  to  remain,
returning  to  it when  moved  to  either side;  and
consequently no  revolution can  be obtained.   Care
should be taken not to  allow the junction to  remain
so long in the flame as to melt the solder.
  205. Double Thermo-Electric  Revolving Arch.
— In  this instrument, two  arches, a and b (Fig. 78),
           Fig. 78.            are so mounted as to
                             revolve  between  the
                             poles of a U-magnet
                             fixed in a horizontal
                             position.   The hori-
                             zontal portion  of the
                             arch  a is of German
                             silver, and the upper
part of silver; while in b, the  lower portion is of
silver,  and the upper  part of  German  silver.   A
single lamp is so  placed as  to heat  both arches;  the
current  excited in  each ascends on its right  side
and descends  on its  left  side, because  the  heat is
applied to the right junction of  a and to  the  left of
6.  Each of them now presents a north pole towards
the north pole of  the magnet, the currents circulating
in the opposite direction to that of the  hands  of  a
watch.  They  consequently both revolve, either in
the same or in opposite directions.   If the arches be
transposed, so  that b occupies the place of a, neither
of them will  move  so  long as the  lamp is  in the
position represented  in  the cut.
 
130
DA VIS'S  MANUAL.
       III.  IN REFERENCE TO THE EARTH.

   206.  A magnetic needle so suspended  as to move
only horizontally, assumes, when left to itself, a deter-
minate direction  with respect to the earth.  Its poles
place themselves nearly in a plane passing through
the geographical  poles of the earth ; this  direction
consequently  corresponds  nearly with the  meridian
of the place where the observation is made.   When
displaced from this position, the needle returns to  it
after  a series of oscillations.   This  directive ten-
dency, and its  probable  discovery by the Chinese,
have  already  been mentioned  in § 11.
   207.  Fig.  79  represents a  magnetic  needle,  so
arranged  as to move  freely in a horizontal  direction
                             only.   The mode  of
                             suspension  is  the same
                             as  in   the  compass
                             needle ; the  latter, how-
                             ever, is fixed  to a cir-
                             cular  card  which  of
                             course moves with  it,
                             and on which the cardi-
                             nal points are  marked.
                                208.  If  the  needle
                             be suspended so as to
                             have  freedom  of mo-
tion in a  vertical  direction, it is found not to  maintain
a horizontal  position, but  one of  its  poles (in this
hemisphere the  north) inclines downwards towards
 
DIPPING  NEEDLE.
131
the earth.   At the magnetic poles of the  earth, the
direction of the needle would be  vertical;  but the
inclination diminishes as  we recede from the poles
towards the equator, and  at  the  magnetic  equator,
which does not vary greatly from  the geographical
one, the needle becomes horizontal.  A needle prop-
erly prepared for exhibiting this inclination,  is called
a Dipping  Needle.
  209.  Fig. 80 represents a dipping needle whose
mode of suspension allows of its  turning freely in
    Fig. 80.     any direction.  It is fixed, by means
               of a universal joint, to a brass  cap
               containing an agate, which rests upon
               the pivot.   The  usual arrangement
               allows only of motion in  a  vertical
               plane,  the  needle   having  an  axis
               passing  through  its middle  at right
               angles to   its  length, which axis is
               supported   horizontally.  This form
               is represented in  Fig. 6.   The small
               needles  in  Fig. 81 are mounted in
               the  same   manner.   Sometimes  a
               vertical  graduated circle is added, to
               measure the angle  which  the needle
               makes with the horizon.   In using a
               needle whose motion is confined to
               a single plane, it must be  so placed
that this  plane may be  directed  north and south,
coinciding  with the plane  of the magnetic meridian.
A  dipping  needle, before  being  magnetized, should
be as equally balanced as  possible,  so as to remain at
 
132
DAVIS'S  MANUAL.
rest in  any direction in which it may be  placed;  a
high  degree  of  accuracy  is,  however,  difficult  of
attainment.
   210.  The dipping needle assumes, in various lati-
tudes, the directions exhibited in the annexed dia-
                              gram (Fig. 81), where
                              the point of  the arrow
                              indicates  the  north
                              pole, and  the feather
                              the  south  pole  of the
                              needles  placed around
                            ;  the  globe.   The an-
                              gle  which the  needle
                              makes with  the hori-
                              zon at  any  place  is
                            .  called the dip, at  that
                              place.  The  tendency
of the needle to dip is counteracted in the  mariner's
and surveyor's compasses, by making the south ends
of needles intended to be used in northern  latitudes
somewhat  heavier  than the north  ends.   A  needle
well  balanced in  this  latitude remains  sufficiently
horizontal  for use in any part of the northern tem-
perate zone,  except for  delicate experiments.  Com-
pass needles  intended to be employed on voyages or
travels,  where great variations  in latitude  may be ex-
pected, are provided with a small weight sliding upon
the magnet.   By a proper  adjustment of  this, the
greater  or  less tendency to  dip  is  counterbalanced.
In passing from the northern to  the southern hemi-
sphere, the weight must be transferred from  the south
to the north pole of the needle.
 
         TERRESTRIAL  MAGNETISM.      \ .'33

  211.  In Fig.  81, the  North American magnetic
pole is represented near S, the north geographical pole
of the earth.   The line L  V is nearly the present line
of no variation (see $ 215), and the curved line near
the  geographical  equator is the magnetic  equator.
where the dip is at zero, and  the direction  of the
dipping needle the  same  as that of  the  horizontal
needle.
  212.  By comparing the directions assumed  by the
needle in its various positions with regard to the earth.
as represented in Fig. 81, with those  assumed  by  a
magnet in  reference to another  magnet, as illustrated
in Fig. 47, a great similarity is found to exist be-
tween them.   This  led  to the opinion, which was
for  a  long time entertained,  that  the  earth  was
itself a magnet, or that it  contained within it large
magnetic  bodies,  under the influence  of  which the
magnetic  needle assumed  these various  directions:
as a small  needle does when placed  in various  posi-
tions near  to  a  bar magnet.
  213.  But there is another mode of accounting for
the directive  tendency of the magnet in  respect to
the  earth;  and that is, by supposing, instead of mag-
netized bodies within the  earth, lying  parallel to the
direction of the needle, currents of electricity passing
around  the earth, within it. but near the  surface, at
right angles with that direction.   This would identity
the  directive  power of the needle in respect  to  the
earth, with its directive tendency in regard to  a cur-
rent of  electricity, as described  under the last head.
And this is, in fact, the view at present adopted.
              12 
134
DAVIS'S  MANUAL.
   214.  The direction of the needle in respect to the
earth is not fixed.   Its variation, that is, its deviation
from the  true  geographical  meridian, is  subject  to
several changes, more or less regular.   So also is the
intensity of the action exerted on it by the earth,  as
shown by the number of oscillations made by it in a
given time.   When examined by means of apparatus
constructed with great delicacy, the needle is found
to be seldom at rest.
   215.  The instrument  represented  in  Fig.  82  is
intended to illustrate  the  magnetism of the earth, on
the supposition stated in $ 212.  The compound bar
                            magnet,  n s,  is  placed
                            in the magnetic  axis of
                            the earth, not coinciding
                            exactly with the axis of
                            rotation, N. S.  A small
                            magnetic needle,  placed
                            at  B,  on  the  magnetic
                            meridian, will point both
                            to  the magnetic pole  s,
                            and to the north pole. N,
                            both being in the same
                            line.  But, if the  needle
be placed  at A, or any where except on the magnetic
meridian,  it will point to the magnetic pole  alone,
the two poles not being in the same direction.   The
several magnets represented at  v s  are  not fastened
together, but only  fixed  on  one axis.   This allows
their poles to be separated a little, to imitate  more
closely the distribution of terrestrial magnetism • the
 
TERRESTRIAL  MAGNETISM.      135
earth  really having  four  magnetic poles, two strong
and two weak:  the  strongest north  pole is in Ameri-
ca,  the weakest in  Asia.   The line of no  variation
on the earth's surface  differs considerably  from the
magnetic  meridian,  and the lines of equal  variation
and equal dip are not exactly meridians and parallels
of latitude to the magnetic  pole.  The action of the
magnetism of the earth  at its  surface is,  therefore,
irregular.
  216.  The variation of the needle at  any place is
found  by observing the magnetic bearing of any
heavenly  body  whose  true  position at the time is
known.   It  is immediately obtained by  comparing
the direction of  the  needle with the north star  when
it crosses  the meridian, or  by calculation  when  the
north st.-ir is at  its  greatest elongation.   An obser-
vation of the sun, however, is usually preferred.  The
                 „.   Q„          latitude of a place,
                 Fig. 83.                      r    '
                                 A (Fig.  83),  be-
                                 ing  known,  the
                                 exact  bearing of
                                 the  sun,  S,  east
                                 or  west,  can be
                                 obtained by cal-
                                 culation,* for any
                                  given moment of
                                  time at that place.
                                  If  the  needle  at
A  points  to  M,  instead  of N, the  true north,  the
* See Bowditch's Navigator. 
136
DAVIS'S  MANUAL.
angle MAS  will  be the magnetic bearing of the
sun west.  Suppose this angle to be observed by the
surveyor's compass, and found equal to 76°, the time
being exactly  noted.   The  angle N A S, the true
bearing  of the sun  at  the  time,  is  then calculated.
Suppose it equal to 85° 30'.   The difference between
the magnetic  bearing  and the  true  bearing,  repre-
sented by the  angle  M A N, is the variation of the
needle,  and equals 9°  30'.*
  217.  Fig. 84  represents an instrument  intended
to illustrate  the theory  which ascribes the magnetism
of the earth to electrical  currents circulating around
it at right angles to its axis.   N S is merely a wooden
axis to  the globe.   When a galvanic current is sent
                       Fig. 84.
through the coil of wire about  the equatorial region,
small magnetic needles, placed in different situations,
arrange themselves as they  would in  similar terres-
trial latitudes.  ' By comparing  this  figure with Fig.

  * The variation at Boston, in May, 1847,  was 9 deg. 30 min
west.  The dip, at the same time, was 74 deg. ^0 min. 
         TERRESTRIAL  MAGNETISM.     137

82, representing the globe with the included magnet,
a comparison may be made between the two theories
of magnetism.   The needles arrange themselves sim-
ilarly on both globes.   With a small dipping needle.
the resemblance  between its  positions  on either and
those assumed by  it on  the earth's surface  is very
striking.
   218.  It  will  be  observed that,  in  Fig. 82, the
south pole  of the  included  magnet  is  represented
near the north geographical  pole of the  earth.  So,
also, in Fig. 84, the rod, N S,  passed through the
axis of the globe, shows the direction of  the polarity
induced by the  current to be contrary  to that  of the
geographical poles.   The  reason of  this may be
easily understood.   The northern magnetic  pole  is
the one which attracts the north pole  of a magnet,
and therefore  must itself  possess south polarity, and
not north,  as  its name might seem to  indicate.  In
Fig. 84, the  battery current is considered as flow-
ing round  the globe in the  same direction  as the
supposed currents in the earth; that is to  say, from
east  to west, in  the  opposite direction to  that  of the
earth's  rotation.   The  apparent  magnetic polarity
induced in  a coil  of wire  by the electric current,
which occasions  the needle  to assume these direc-
tions, will  be described under a subsequent  head.
   219.  The  aurora borealis  is  found  to  affect  a
delicately-suspended magnetic needle,  causing it to
vibrate constantly, but irregularly, during  its continu-
ance, and especially when the auroral  beams  rise to
the zenith; if the  aurora is near the horizon, the
              12* 
138
DAVIS'S  MANUAL.
 disturbance of the needle is very  slight.   When  the
 beams unite to form a corona, its  centre is generally
 in or near the magnetic meridian.
   220.  Within a few years,  a considerable number
 of magnetic  observatories have been established in
 various parts of the world, for the  purpose  of making
 systematic and corresponding  observations in relation
 to terrestrial  magnetism.   At  these stations the vari-
 ation of the  needle, and  the  intensity of the earth's
 action  upon  it, are observed and recorded  almost
 hourly,  and  on  stated days  at  intervals of a few
 minutes only.  These observations,  made by means
 of excellent  instruments,  and at  the same  time in
 widely remote regions,  admit  of comparison  with
each other, and can hardly fail  to throw light  on
many parts of this  important and intricate  subject. 
MAGNETISM.
                      n.

       INDUCTION  OF MAGNETISM.

     I.  BY THE INFLUENCE OF A MAGNET.

  221.  A piece of iron, of any form, brought near to
a steel  magnet,  becomes itself  magnetic  by induc-
tion.   Thus, let M  (Fig. 85) be a bar magnet of
             p.   g5             steel,  and  B an
                               iron  rod  brought
                               near to it.  By the
                               influence   of  the
magnet the rod will become magnetized ;  the end
nearest  the  south  pole will become north,  and  the
end remote from it, south.  The magnetic induction
is stronger when the bar is brought in  contact with
the pole of the magnet; a decided effect, however, is
produced  by the mere proximity of the  magnet to
the iron.  That the  iron bar, while under the influ-
ence of the magnet, actually possesses magnetic prop-
erties, may be shown  by presenting to  it some iron
filings or  small nails, which will adhere to  each ex-
tremity;  and also by bringing near to  it  a small 
140
DAVIS'S  MANUAL.
magnetic  needle balanced on a pivot, the north pole
of which will be repelled by the end of the bar nearest
to the  magnet, M, and attracted  by the end farthest
from M.   This induced magnetism  immediately dis-
appears when  the  iron is removed from the vicinity
of the magnet.   If a small bar of steel be substituted
for the iron bar,  it acquires  magnetism much  less
readily, but retains it after  removal;  becoming, in
fact, a permanent magnet.
   222.  It was formerly supposed that  the attractive
force  of  the loadstone,  or any  other  magnet, was
exerted upon  iron simply as  iron; but it  is now
known to be the attraction of one pole of a magnet
for the opposite pole of  another  magnet.    In  all
cases, when a  magnet is  brought near to or in con-
tact with  any magnetizable bodies,  as pieces of iron.
iron  filings, or ferruginous  sand,  all  such  bodies,
whether  large  or  small,  become magnetized ;  the
part  which  is nearest to  either  pole of the magnet
acquiring  a polarity  opposite  to that  of  this pole,
while the remote  extremity  becomes a pole  of the
same  name.
   223.  The north pole of a bar magnet, M (Fig.
86),  placed  on the centre of  a circular  plate of iron,
induces south polarity in  the  part  immediately be-
neath it, and  a weak north  polarity in the  whole
circumference, so that it will  sustain iron  filings, as
shown in  the  cut.   If an  iron plate is cut into the
form of a star, as  in  Fig.  87, each  point acquires a
stronger north  polarity than the edge  of the  round
plate in Fig. 86, and is able to lift several iron screws 
INDUCTION  OF  MAGNETISM.
141
or nails; the  letters in the cut  indicate the position
of the poles.
           Fig- 86.                  Fig. 87.
Fig. 88.
   s
  224.  Let the north pole of a steel  magnet, N S
(Fig. 88), be placed on the middle of a bar of iron.
                    The part of the bar  in  contact
                    with  the  magnet  becomes a
                    south pole, while north polarity
                    is distributed along both halves
                    of the bar.
                      225. If several pieces of iron
                    wire,  of  the  same length, be
                    suspended from  a magnetic pole,
                    they do  not hang parallel;  but
                    the  lower  ends  diverge from
                    each  other,  in  consequence of
their all receiving  the same  polarity  by  induction,
 
142
DAVIS'S  MANUAL.
while the upper ends are retained in their places by
the attraction of the  magnet.  Let two short pieces
of iron wire be suspended by threads of equal length,
fastened  to one end of each piece, so that the wires
may hang in contact.  If,  now, the south pole of a
magnet be placed below the wires, the lower  ends
of both will become north poles, and  their upper ends
south  poles; and  the wires will  recede  from  each
other.  This divergence  increases as the magnet is
brought nearer, until  it reaches a certain limit, when
the attraction of the magnet for the lower poles over-
powers their mutual  repulsion, and causes them to
approach  each other; while the repulsion  of the
upper  ends  remains  as before.
   226.  The mutual  repulsion of two pieces of iron
magnetized  by induction may also be shown  by the
   Fig. 89.   arrangement   represented  in Fig. 89.
            There are two short pieces of iron wire,
            upon the ends of which are  secured
            little brass rings, which answer the pur-
            pose of  rollers.  The  two wires being
            placed together, as  represented by the
            dotted lines at A, let a U-magnet, held
            in a vertical position  over them, be grad-
            ually brought  near, keeping the poles in
            the direction of the length of the wires.
As the magnet approaches, the wires become charged,
the similar poles lying in the same direction.   When
the magnet is brought so near as to occasion sufficient
repulsion  between the induced poles, the wires re-
cede from each other, as shown at B B, in the cut.
 
ATTRACTION  OF  ARMATURE.    143
  227.  Y-Armature.—This consists of a piece of
soft iron, in the shape of the letter Y.   If one of the
    Fig. 90.    branches of the fork be applied to the
              north pole of a horseshoe  magnet, as
              seen in Fig.  90, the lower end of the
              armature, and also  the  other branch
              of the  fork,   acquire north  polarity,
              and  will sustain  small pieces of  iron.
              If both branches of the fork  be ap-
              plied, one to each pole of the magnet,
              as shown by the  dotted lines  in the
              cut, the polarity of the lower end im-
              mediately  disappears.   This  is be-
              cause the  two poles tend  to  induce
              opposite polarities of equal intensity in
              the extremity of  the armature, which
of course neutralize each  other.   If the branches of
the fork are applied to the similar poles of two mag-
nets, their influence will conspire  in  inducing the
same polarity in the lower end, and  a greater weight
will be supported by  it, than when one branch is
applied  to  a single  pole.
  228.  When the two extremities of an iron bar are
acted upon at once by both  poles of a magnet, there
is  a double induction, and  the  effect  is  greatly in-
creased.   Thus,  let N S  (Fig.  91) be a compound
U-magnet, and A an iron  armature, of such a length
that, while one end is applied to  the  north pole of the
magnet,  the other extremity may be applied to the
south.   In this case,  both  poles of  the magnet act,
each inducing a polarity opposite to its own in that
 
144           davis's  manual.
Fig. 91.
extremity of  the  armature  which  is under  its influ-
ence.   The force with  which the armature adheres
           is consequently greatly  increased, there
           being a  strong attraction between each
           pole of the  magnet and  the correspond-
           ing  extremity  of  the  armature, that  is,
           corresponding in position ; for  the polar-
           ity of the parts in contact will evidently
           be of opposite  denominations.   If a  bar
           of iron is placed between the north poles
           of  two  magnets,  both  extremities  be-
           come south poles, while a  north pole is
developed at the middle of the bar.
                    229. Rolling Armature.—This
                 apparatus consists of a  horseshoe
                 magnet  and an  iron  wire or rod,
                 whose length is a little greater than
                 the breadth of  the magnet.  To
                 ihe middle of the wire a small fly-
                 wheel is  attached.   This  armature
                 is  placed across the magnet, at some
                 distance  from the  poles,  and  the
                 magnet  held in such a  position,
                 with the  poles downward, that the
                 armature may  roll towards them.
                 When it  reaches  the  poles,  the
                 magnetic attraction of the iron axis
                 prevents  its falling off, while  the
momentum acquired by the fly-wheel carries  it  for-
ward, causing it  to  roll some distance  up the other
side of the magnet.
 
MAGNET  AND  ROLLER.        145
   230.  Magnet and  Roller. — Some of  the  phe-
 nomena of magnetic attraction and repulsion  may
                            be shown  by  the ar-
                            rangement   represented
                            in  Fig. 93.   The poles
                            of  the  steel  magnet,  N
                            S,  are  raised  by a little
                            wooden  block, and  a
 piece of iron,  A, is placed across, near the bend.  A
 short iron  wire, K, has a brass  ring encircling each
 end, which prevents actual contact  between the iron
 and the magnet,  and thus  allows  the  wire to roll
 freely.  When  K  is placed  in  contact with A,  it
 immediately rolls up the  magnet,  in opposition to
 gravity,  until  it  nearly  reaches  the poles.   The
 actual poles or points of  greatest magnetic  intensity,
 in a steel magnet, are not  exactly  at the  ends, but
 a  little  within  them.  They  are  so near  that it is
 usual to give  the name  of poles  to the extremities
 themselves.  Upon bringing up the armature, R, to
 the poles, the  wire, K, is repelled  by it (see ■§> 226);
        and from this cause, and  the diminished ac-
        tion of the magnet upon it, the  wire rolls
        back towards A. Being repelled by A, it takes
        a position of equilibrium near it;  and when
        R is removed, again rolls up the magnet.
           231. With a small magnet, whose poles
        are brought near together,  as represented in
        Fig.  91, the attractive  force is sufficient to
        raise  the wire up  to the poles, even  when
the magnet is  placed  in a  vertical  position.
              13
 
146           davis's  manual
  232.  Fig. 95  illustrates the  successive  develop-
ment  of magnetism in several  bars of iron.   The
    m    Fig 95.   a    be  bar  a  being  placed
sm&-
zifi
b
p near to or in contact
Fig. 96.
with the north pole of a  magnet, M, becomes itself
temporarily magnetic, and is able to induce magnet-
ism in a second bar, b, this again in c, and  so  on,
each  succeeding  bar being  less  and less strongly
magnetized.  The  same  thing occurs  with the iron
nails  represented  in Fig.  87, hanging from  the
points  of  the star.  If the  magnet, M,  be removed
from the bar a, the magnetism of the whole  series
disappears.
                      233.  When a  bar  magnet is
                    placed  in  a heap  of iron filings,
                    and  then  lifted  up, the  filings
                    attach  themselves to  the poles
                    in  clusters.   Each  particle  be-
                    coming a  little  magnet, they
                    adhere  together in lines,  whose
                    length  depends upon  the pow-
                    er  of  the  steel magnet.   A
                    U-magnet, plunged into a mass
                    of  tacks, sustains long lines of
                    them,  as represented in Fig.
                    96.   The chains of tacks sus-
                    pended from the two poles at-
                    tract each other, and, becoming
                    connected, form  curved  lines,
                    rudely  representing the  mag-
netic  curves  spoken of  in <§> 147.
 
LOADSTONE
147
  234.  Loadstone. — The  arrangement  of  small
brads around the  poles of a loadstone,  is represent-
Fig. 97.
                               ed in  Fig.  97.    In
                               natural  magnets  the
                               poles  are  not usually
                               so distinctly  marked
                               as in artificial  ones,
                               the   magnetic  forces
                               being more irregularly
                               distributed.
                                 235.  The attrac-
                               tion of a magnetic pole
                               for a piece  of  iron
                               is not  exerted  upon
                               the whole  mass, since
                               both  a north and  a
                              south pole  are neces-
                              sarily developed in the
                              iron.  Hence only that
 part of the piece which is nearest the magnet can be
 attracted, while  the remote end must be repelled.
 If the piece of iron has any considerable  length, the
 end which is repelled will be at such a distance from
 the influence of the magnet, that its repulsion will be
 overpowered by the attraction of the extremity which
 is near it.   If, however, the piece  is very short, so
 that the repelled  pole is brought near to the magnet.
 the repulsion  is  proportionally  stronger, neutralizing
 the attraction  to  a  considerable extent; and, finally,
if the iron is of such a form as to bring the two oppo-
site poles as near together as possible, so as to expose
 
148
DAVIS'S  MANUAL.
them  nearly equally to the influence of  the magnet,
the attraction  becomes scarcely perceptible.   Thus,
let M (Fig. 98) be  the south pole of a bar or horse-
     r*.  na       shoe magnet, and A a piece of sheet
                 iron  somewhat  smaller  than  the
                 end of the  magnet.  When this
                 iron plate is placed in  the position
                 represented in the upper figure, the
                 surface next the pole of the magnet
                 acquires north  polarity, while the
                 opposite  surface  becomes  south;
                 and, the  iron being thin, the two
                 surfaces are  both so  near  to the
magnet that one  is  repelled  nearly  as much  as the
other is attracted.  The thin plate will  be found to
adhere to the  pole  with  a very slight  force, txv.d will
tend  to slip down  into  the  position  represented  in
the lower figure.  In this position it is much  more
strongly attracted ; for  the two ends, instead of the
two surfaces,  become the poles, and  the end in con-
tact is attracted,  and the remote  end repelled.   The
same effect  will  be produced if  the  plate is applied
to the pole of the  magnet by its edge, instead  of
by one of its surfaces;  by this  means,  the  repelled
pole of the  plate is removed  to  a distance  from the
magnet.
   236.  The inductive action  of  a magnet is not im-
peded by the interposition of any  unmagnetizable
body whatever,  If  a plate  of glass be placed be*-
tween the magnet and  a  piece  of  iron, the  iron  is
attracted  as strongly as it  would  be at the  same 
ATTRACTIVE  FORCE.          149
distance  with no glass interposed.   Fig.  99  repre-
sents  a piece of iron wire,  sealed  up hermetically
   Fig. 99.    in a glass tube.  When this  is applied
             to a U-magnet, the iron  is attracted with
             sufficient force to hold  the tube in con-
             tact with  the poles.   The polarity  in-
             duced in the iron  is precisely as great
             as  when only air  is interposed.   The
             result  is the same when the iron is en-
             closed in a tube of brass, or any metal
not susceptible  of  magnetism.
  237.  Fig. 100 represents an  instrument designed
to measure  the force of  attraction between a  U-
masinet and  its armature  at different distances.   It
          Fig. 100.
fit \i\ |3i |4I"|ji |gi ivi isitiji iw mi iin-rnnr
is  on the  principle of the  steelyard.   The beam,
which is of brass, is supported by steel knife edges,
resting in curved supports of the same metal.   To
the shorter arm of the beam is secured the armature,
consisting of a  small  cylindrical bar of iron.   The
force with  which this is held down  is  measured  by
              13* 
150
DAVIS'S  MANUAL.
 weights hung upon the graduated longer arm.  The
 magnet is  held firmly against a vertical brass plate,
 by means of a clamp of the same metal, which allows
 the poles to  be  fixed  at any required distance from
 the armature.  The distance was determined in  the
 following way:  Sheet brass of ^o of an  inch in
 thickness was taken, and  several series of different
 thickness formed by pressing strips of it firmly  to-
 gether and soldering them at the edges.   By inter-
 posing these strips between the magnet and armature,
 they were maintained  at any desired distance, from a
 single thickness, or  -^^ of  an inch, up to ten thick-
 nesses, or 2? °f an  inch.
   238.  The  following tables were constructed from
 experiments  with two steel magnets,  of  different
 lengths, and a long electro-magnet.   The  first mag-
 net employed was a very short  one, formed from  a
 steel bar, \ inch square.  It was  If inches long,  and
 \\ inches between  the poles.  The  first column in
 the table gives the number of brass strips interposed,
 the magnet and armature  being  at  first in contact.
 The second column gives the  weight  sustained, or
 the force of attraction, in grains; and the third,  the
 product obtained  by multiplying  the weight in each
case by the number of interposed strips.  There is
a very slight spring in the brass, which diminishes
as the  number  of  strips  is increased.   In  conse-
quence  of  this,  the  armature  is removed  slightly
beyond the calculated distance,  and  the weights in
 the first  part of  the table fall a little below the true
proportion. 
ATTRACTIVE  FORCE.
151
Table I.
Distance.	Weight in Grains.	Product.
0 . . .	. . . 21,200	
1 . . .	. . . 4,000 . . . .	. . 4,000
2 . . .	. . . 2,170 . . . .	. . 4,340
3 . . .	. . . 1,500 . . . .	. . 4,500
4 . . .	. . . 1,220 . . . .	. . 4,880
5 . . .	... 970 ... .	. . 4,850
6 . . .	... 810 ... .	. . 4,860
7 . . .	... 670 ... .	. . 4,620
8 . . .	... 595 ... .	. . 4,760
9 . . .	... 500 ... .	. . 4,500
10 . . .	... 445 ... .	. . 4,450
  239.  The second steel magnet was of  the same
thickness and width, but 11 inches long.   The re-
sults obtained with this are given in  Table II.
Table II.
Distance.	Weight in Grains.	Product.
0 . . .	. . . 62,500	
1 . . .	. . . 32,000 ....	. . 32,000
2 . . .	. . . 17,300 ....	. . 34,600
3 . . .	. . . 13,100 ....	. . 39.300
	. . . 9,600 ....	. . 38,400
	. . . 7,800 ....	. . 39,000
6 . . .	. . . 6,800 ....	. . 40,800
7 . . .	. . . 5,600 ....	. . 39,200
8 . . .	. . . 4,700 ....	. . 37,600
9 . . .	. . 4,050 ....	. . 36,450
10 . . .	. . 3,600 ....	. . 36,000
 
152
DAVIS'S  MANUAL.
  240.  The third  series of experiments  was  made
with an electro-magnet,  9| inches long, formed from
a round bar,  1 inch thick.  Its poles were 1-} inches
apart.  The results, with one pair of Smee's battery,
are given in the following table : —
	Table III.	
Distance.	Weight in Grains.	Product.
0 . . .	. . . 82,000	
1 . . .	. . . 35,000 . . . .	. . 35,000
2 . . .	. . . 25,000 ....	. . 50,000
o		. . 60,000
4 . . .	. . . 15,500	. . 62,000
	. . . 12,100	. . 60,500
6 . . .	. . . 11,300 . . . .	. . 67,800
	. . . 9,300 ....	. . 65,100
8 . . .	. . . 7,400 ....	. . 59,200
9 . . .	. . . 6,500 ....	. . 58,500
10 . . .	. . . 5,500 ....	. . 55,000
   241.  It will be seen that the numbers in the third
column of Tables I. and II. agree sufficiently well to
give the following practical rule for finding the rela-
tive attractive force at different distances; that, with
steel  magnets of  any length, the force with  which
the armature is  attracted varies in  the inverse ratio
of  the  distance.   The third column  in Table III.
shows that the  electro-magnet does not follow this
proportion.  If the  points of  strongest polarity  are
regarded as situated a little within  the  ends of  the
magnet, for instance, at & of  an inch, or the thick- 
ATTRACTIVE  FORCE.         153
ness of  five strips of brass,  in  the  above tables, the
distances calculated from these will give very nearly
the  true  law,  as stated  in  <§> 142.   A  still  closer
approximation might probably  be  made.
  242.  Table IV.  gives  the  comparative attractive
force of the long  steel magnet, with the armature in
contact, and when separated by a single thickness of
brass, the  charge  of the magnet being progressively
reduced.  In the  first column are given the weights
sustained  in  grains, the armature  being in contact
with  the  poles;  in the  second,  the corresponding
weights when their distance  was -^io  °f aa incn'

                    Table  IV.
         In Contact.              Distance, ■Z^JS.
          62,500.........32,000
          52,500.........28,000
          33,500.........10,900
           6,600.........  2,280

  243.  The same  instrument was used to  measure
the force of attraction between the opposite poles of
two bar magnets.   These were made  from  the same
square bar of steel, and  were each 6 inches  long  and
-fe of an inch thick.  One of them being suspended
vertically from the  shorter arm of the brass  beam,
the  other  was secured to  the brass  plate perpen-
dicularly below the  first.   The poles  were  placed in
contact  in the first experiment, and afterwards sepa-
rated to different  distances from ^fo to ^ of an inch,
by  strips  of brass, the  lower  magnet  being moved 
154
D A V I S ' H  MANUAL.
sufficiently to keep the beam horizontal.   Beyond
5^ of an inch, the instrument was not delicate enough
to give the weight with sufficient accuracy.
   244.  In Table V. are given  the results  of  this
series of experiments.

                    Table  V.
       Distance.                  Weight in Grains
          0.............6,000
          1.............3,100
          2.............2,200
          3.............1,900
          4.............1,600
          5.............1,300
          6.............1,200
          7.............1,100
          8.............   980
          9.............   890
         10.............   770

   In  the first experiment  in the  table,  the poles
touched  by  their whole  surface.   By  moving  the
lower  magnet laterally until the  edges only of the
poles were in contact, the  force  of attraction  was
considerably  increased, being equal to 10,000 grs.
   245.  By considering the points of strongest polar-
ity, or the true poles, as situated at a distance of  four
and  a half strips of brass within  the ends of each
magnet,  the  results given in Table V.  are  made to
agree closely with the law of the inverse ratio of the
square of the distance. 
ATTRACTIVE   FORCE.
155
  246.  The following table gives the attractive force
between one of the bar magnets and  a straight bar
of iron, 6 inches long : —

                    Table VF.
        Distance.                  Weight in Grains.
          0.............5,600
          1.............1,480
          2.............   870
          3.............   670
          4.............   520
          5.............   410
          6.............   360
          7.............   300
          8.............   270
          9.............   240
          L0.............   200

   These numbers may  be brought  under the  law
stated  in <§> 142, by calculating the distances from a
point TV of an inch within the steel magnet.  In the
iron  bar, as in  the armatures of  the U-magnets, the
poles are  probably  situated at the surface.
   247.  A  close  analogy  exists  between  the  phe-
nomena of  magnetism and of statical electricity in
many  important  points.   But in  some  respects  it
fails.   Electricity, whether positive or negative, can
be transferred from one body to another, so that a body
may be charged with an excess of electricity of either
kind.  It  is not so with magnetism.   Every magnet
possesses  both  polarities to an equal degree, though
they may be diffused through portions of its mass of 
156
DAVIS'S  MANUAL.
different extent.   A long conductor, exposed to  the
inductive influence  of an electrified  body, has oppo-
site electricities developed at its ends.   If, now, it be
divided in the middle, we obtain the two electricities
separate; one  half  of the  conductor possessing an
excess of positive, the other of negative  electricity.
The condition of  a  magnet in regard to the distribu-
tion of its polarities appears to be  exactly analogous
to that of the conductor; the north polarity seeming
to be collected in  one half of its length, and the south
in the other.  We  might, therefore, expect that, by
breaking the magnet in halves, we should obtain the
two polarities  separate,  one in each portion of the
bar.  But such is not the  case;  each  half at once
becomes a perfect magnet.  In Fig.  101, which rep-
resents a fractured  magnet, the original  north  pole

                      Fig. 101.
          fs            ■"■J/s          ~s\
          tmrnTiiiiiiiiiiiiiiiimwiiiMiniiiiiniilllllilliiiiiiiiiiiffaiiiiiiiii..........iimiiimiiiiiimiiiiniini.....nuindi m tinui, H

still remains north,  but  the broken end of the piece
has  acquired a south pole.  The  converse occurs
with respect to the other portion in which the south
pole was situated.   These halves may be again broken
with the same result; and, in fact, into however small
fragments  a magnet may  be subdivided, each  will
possess a north and a south pole.
  248.  Suspend  a  piece of iron from one pole  of a
magnet, and bring up to this pole the opposite  pole
of another  magnet.   The  iron immediately falls;
the poles, when in  contact, neutralizing each other, 
ELEMENTARY  MAGNETS.        157
and corresponding to the middle or neutral portion of
a magnet.  If the piece of iron is nearly as heavy as
the pole  can  sustain, it falls on the mere approach of
the other magnet to the pole, and before it touches it.
   249.  In order to explain the distribution  of the
magnetic forces and the results of fracture, it is ne-
cessary to regard a magnet as made up of minute,
indivisible particles of steel, each of which possesses
the properties of a separate  magnet.   Fig.  102  is in-
                  tended to give an idea of the mode
                  of arrangement of these elementary
                  magnets; they  are, of  course, so
                  minute as to be beyond the reach
                  of the most powerful microscopes.
                  All  their  poles  lie in the  same
                  direction, as  indicated by the light
                  and shaded portions in the cut; the
                  light half of each little magnet rep-
                  resenting its  north pole, and the
                  shaded half its south pole.  These
             N    poles are  distributed  through the
 whole length of the bar ;  but in consequence  of their
 mutual reactions, the resultant polarities are strongest
 near  the ends of the bar,  becoming more  and  more
 completely neutralized towards  the  middle.
   250.  Artificial magnets  were  formerly made by
 induction  from  strong magnets previously  prepared:
 the original  source of the  power  being  natural mag-
 nets, or the  magnetism  of the earth.   When this
 was the case, it became important to ascertain what
 arrangements, and what modes of applying a magnet
              14
 
158
D A VI S ' S  MANUAL.
to a bar or needle,  were most efficacious in com-
municating or developing the magnetic power;  and,
accordingly, various and complicated  arrangements
and manipulations for  this  purpose, are detailed in
old treatises on the science.  Recently, other  and far
more powerful means have been discovered for mag-
netizing bars of  iron or steel, by the aid of electro-
magnetism ; so that the old methods have been, in a
great measure, superseded.   The induction of mag-
netism by  means of  steel magnets  is now only
employed for needles or small bars.
  251. It may,  however, be convenient to know  a
good process  for magnetizing  (or touching,  as  it is
technically  called) with steel magnets.  One of the
simplest and best for a small straight bar is  the fol-
lowing: Place the  middle of  the bar on one of the
poles of either a straight or a U-magnet, and draw
one end of it over the pole  a  number of times;  the
direction of the motion  being always from the middle
to the end.   Then turn the bar in the hand, and pass
the other half over the other  pole of the magnet in
the same way.   If the bar  is thick, the process may
be repeated with its different sides.  The end which
has been drawn over the south pole of the  magnet
will now possess north polarity, and  the other ex-
tremity south polarity.  A  U-magnet is more readily
charged by drawing over it the poles  of a steel  U-
magnet, of  corresponding width, in the same  manner
as in the process, which will be described farther on,
for touching with electro-magnets.
   252. The  magnet which is used to induce mag- 
     E L E C TRO —M AG NET I C  INDUCTION.  159

netism loses none of its own power in the process, but
often  receives a permanent increase by the reaction
of the polarities it  has  induced  upon  its own.   A
magnet, whose armature  is kept constantly applied,
not only retains its  power without loss, but acquires
a  further  increase  up to a  certain limit.  That  a
magnet possesses greater power  while exerting its
inductive action, may be  shown  by suspending from
one pole of  a bar  magnet  as much iron as  it  can
hold.   If, now, a bar of  iron  be  applied to the other
pole,  the  first  will  be found  capable  of sustaining
a  greater  weight than before.


   II.   BY  THE  INFLUENCE  OF  A  CURRENT OF
                  ELECTRICITY.

   253. It  has already been  stated, under the head
of the directive tendency  of a magnet  in reference to
a  current  of electricity, that a magnetized  body,
freely suspended within the influence  of  such a  cur-
rent,  tends to assume such a position that the  line
joining its poles may be  at right angles to it.   It  is
also found, that, if any magnetizable body be  placed
in the vicinity of  an electrical  current,  it acquires
magnetism  by its influence.   This phenomenon  is
termed electro-magnetic induction.  The present chap-
ter,  and  the  one  referred to above,   form together
the department of  electro-magnetism.
   254. In Fig. 103 is given a  sectional  view  of a
series of four pairs  of Grove's battery, whose poles
are connected by a copper wire, in which the  current 
160
D A V I S ' S  MANUAL.
is  flowing  in  the direction of the  arrow.  A small
iron rod, or short piece of iron wire, placed vertically
in front of  the horizontal portion of the copper wire,
becomes instantly a magnet, with its north  pole
below  the  wire.   The  direction of the induced po-
larity is reversed by transferring the iron  rod to the
other side  of the  wire.   The  rod  being placed in a
horizontal  position above the  wire, its north  pole is
turned towards the observer;  if below the wire, it is
directed from  him.  By carrying  the rod  around the
                      Fig. 103.
wire, keeping  it transverse, it will be seen that the
induced poles  retain their  relative position with re-
gard to  the  current.   As  the rod is carried round,
the end which was a north pole  in  the  position
shown in the cut,  remains north in every part of the
revolution.   The rod  attracts iron filings,  and acts
upon  a delicate  magnetic  needle, brought  near it,
like a  steel  magnet;  but its polarity instantly dis-
appears,  when  it  is removed from the  influence of
the current.  The induction diminishes as the rod is
removed farther from  the wire;  but it  is not inter-
fered  with by the  interposition  of any bodies  not
susceptible of magnetism. 
            DIRECTION  OF  POLES.        161

  255.  A  sewing needle, placed  transversely across
the wire, becomes magnetic  in the  same way, and
retains  a portion  of its  power when  removed.  If
placed parallel to the wire, it acquires feeble polarity
on its opposite sides, instead of in  the direction of its
length,  and probably will not retain it after removal;
it  being very difficult to  maintain  this transverse
distribution of magnetism in  magnets  whose length
considerably exceeds their  diameter.
  256.   Though the  relation  between the  electric
current  and  the direction of the  polarity which  it
induces is  fixed and determinate, yet  it  is very dif-
ficult to express.   The  same law which  has  been
stated, in § 153, as governing  the  motion of a  mag-
netic  pole  brought near  the  current,  regulates the
direction  of the induced magnetism.    It  is  con-
venient to reduce this to a rule,  by which the po-
sition of the poles may be readily found in all cases.
  257.  The following mode  of  fixing  the  rule in
the memory, is  perhaps the best that has been con-
trived.   First, it is more  natural to fix  our attention
on the current of positive  than of negative electricity.
Secondly,  in a  vertical wire,  a descending  current
will occur to us  more readily than an ascending one ;
or, if  we imagine  ourselves borne along  by the cur-
rent, it would be more natural to  conceive  ourselves
moving with our feet foremost;  but  if, on the con-
trary, we suppose  ourselves to  be  at  rest, we should
conceive the current  to  be  passing  from our  head
to  our feet.  Our face would, of course, be turned
towards  the body to  be magnetized;  we  should
              14* 
162
DAVIS'S  MANUAL .
attend to  the north pole in preference to the south ;
and to our right hand  rather than to our left.  Com-
bining these conditions, then, we may always recol-
lect,  that, if  we  conceive  ourselves lying in  the
direction of the current,  the stream of positive elec-
tricity flowing through  our head towards  our feet,
with  the  bar to be magnetized before  us, the north
pole of that bar will always  be towards our right
hand.   If any one of these conditions  be  reversed,
the result is reversed  likewise.
  258.  Though  a single magnetic pole is neither
attracted nor repelled  by a conducting wire (<§> 152),
the tangential  action of the  current upon both poles
of a needle, situated as in Fig. 103, causes  it to  ap-
proach  the  wire.   This result  may be  shown  by
placing the conducting  wire  in  a  vertical  position,
and presenting to it a  needle suspended in a horizon-
tal position by a  thread.    When  the needle is re-
moved  to  some  distance, or  when very short,  the
attraction becomes insensible.  From the feeble mag-
netizing power of  the wire, this experiment is best
performed with  a needle  previously charged.   If
the needle is  brought up to the wire with  its poles
in the reverse  direction  to those of the iron rod in
Fig. 104,  or if, without changing their direction, it is
carried to the other side of the wire, it is repelled by
the combined  tangential  forces.
  259.  Fig. 104 illustrates  the  action of the forces
in  producing   attraction  and  repulsion.   W repre-
sents a horizontal section of the conducting wire, in
which the current is ascending ;  and N S a  magnetic 
TANGENTIAL  FORCES.         163
needle,  whose  poles are at equal distances from the
wire.   From  W, as a  centre,  a circle  is  drawn,
Fig. 104.
Ow
                          passing through the poles.
                          The forces  which move
                          the magnet are tangents
                          to  this  circle,  and  their
                          directions are indicated by
                          the arrows.   It  will  be
                          seen that the resultant of
                          the forces, acting on each
                          pole, urges the centre of
                          the magnet towards the
wire.   If the  magnet  be transferred to the position
N' S', on the other side of the  wire, its centre is urged
away from it.   The force  increases in proportion as
the magnet is  nearer to the wire.
  260.  When the poles are  at different  distances
from the wire, the resultant of the  tangential forces
                               moves  the  magnet
Fig. 105.
E
 /
P
 \
• w
obliquely   towards
the  wire,  until  its
centre  comes  into
contact with it.   If
there are  two cur-
rents   moving   in
opposite directions,
one on  each side of
the magnetized  bar, and at equal distances from it,
their combined  action  urges  the bar forward  until
its centre  comes  into the same line with the wires.
In Fig.  105, let  W be a horizontal section of a  wire, 
164           DAVIS'S  MANUAL.
 in which the current is  ascending,  and W one in
 which it is descending.   The four  small  arrows
 indicate the tangents to the circles, drawn as  in Fig.
 104, from W and  W as centres.  At the  south pole
 of the bar, the direction of  the forces is nearly oppo-
 site, and  they neutralize each other in a great degree:
 at the north pole, they approach to  parallelism, and
 that pole is  urged forward by a force nearly equal to
 the sum  of  the two.   As this force is opposed only
 by the feeble one at the south pole, the bar moves in
 the direction indicated by the arrow below.  When
 the magnet  is not  equidistant  from the wires, it no
 longer moves in the direction of its length, as in the
 cut, but its centre is drawn  towards the  nearest wire,
 with a force which is accelerated as it approaches.
   261. A short copper wire, connecting the poles of
 a  battery, will sustain  iron  filings, as  represented  in
 Fig.  106.  The  lines of filings have  not  that  bris*
        Fig.  106.         tlmg) divergent  arrangement
                        which they  exhibit  under
                        the influence of a steel mag-
                        net, but adhere equally all
                        around the circumference of
                        the  wire;  forming circular
                        bands, the particles of which
                        mutually cohere in  conse-
                        quence of each  particle be-
                        coming  a  magnet  with its
                        poles transverse  to the wire.
                        The influence  is  equal at
every part of the length of the wire;  hence these
 
HELIX,  ON  STAND.
165
transverse bands, lying  in  contact  with each other,
present the appearance of a closely-compacted layer.
Whatever form the metal conducting the electricity
may have, the filings will always arrange themselves
in lines  encircling it at  right angles to the course of
the  current.   The iron  filings fall off when the cur-
rent ceases to flow; but if steel filings be employed,
part of them remain attached, in  consequence of the
adhesion of the magnetized particles  among them-
selves.   A short wire is  better for this experiment
than one of considerable  length ; and  a battery of
some  power, such  as a  series of a  few pairs of
Grove's, may be  used with advantage.
  262. Helix, on Stand. — The magnetizing power
of the wire is very greatly increased by  coiling  it in
                     Fig.  107.
the manner  of a corkscrew, so as to form a hollow
cylinder, into which the body to be magnetized can
be  inserted.   Such a coil  is denominated a  helix, 
166           DAVIS'S  MANUAL.
and  is  represented  in  Fig. 107,  mounted upon a
stand.   A single circular turn is more efficient than
the straight wire, and each turn adds to the  power
within a certain  limit, whether the whole forms a
single layer, or whether each successive turn encloses
the previous one in the manner of a spiral.   When a
helix of great power is required, it is composed of
several  layers of  wire.  The wire forming the  coil
is insulated by being wound with cotton, to prevent
any  lateral passage  of  the  current.
  263.  Place a  bar of  soft iron within the coil, and
connect it  with  the battery by means of the  two
cups attached to the stand.   The two extremities of
the bar instantly become strongly magnetic, as  will
be seen by bringing a key,  or other piece of iron, in
contact with  them.   On separating one of  the wires
communicating with the battery, the magnetic  powei
of the  iron bar  will  be immediately destroyed, and
the key will drop.  If iron  filings, or small nails, are
held near one of the extremities of the iron, they are
taken up and dropped alternately, as the connection
with the battery is made or broken.  By bringing a
magnetic needle near the two extremities of the bar,
in succession, one  of them will  be found to have
north and  the other south  polarity, and   they  will
attract  and  repel the poles of the needle accordingly.
A  bar,  temporarily  magnetized by an electric  cur-
rent, is called an  electro-magnet.
  264.  The  following rule indicates  the  extremity
at which the  north  pole will be found.   If the helix
*e placed before the observer with one of its ends 
ACTION  OF  HELIX.
167
towards him, and the current of electricity, in passing
from the positive to the negative pole of the battery,
circulates in the coil in a direction similar to that of
the hands  of a watch, or the threads of a  common
screw, then the north  pole will be from the observer,
and the south pole towards him.   If  it passes round
in the contrary direction, the poles will be reversed.
Or the formula may be stated thus :  The north pole
will be at the farthest end  of the helix when  the
current circulates in the  direction  of  the hands  of a
watch.  By comparing this  rule with that  given  in
§ 257, for  a straight wire, it will  be  seen  that  it is
directly deducible from  it.
  265.  Place a  steel  bar, instead of an  iron  one,
within the helix.  It acquires polarity somewhat less
readily, but the polarity will continue after the con-
nection with the battery  is broken.   Any small rods
or bars of  steel,  needles,  &c, may be made perma-
nent  magnets in this  way.   Bars of iron,  or  steel,
brought  near the outside of the  helix, obtain  po-
larity in a much  feebler degree.   An iron tube docs
not become  perceptibly magnetic when a current is
passed through  a helix  placed within  it, though it
becomes strongly so when enclosed  in a helix suf-
ficiently large to  admit it.  If two soft  iron bars are
inserted in the helix,  at the opposite  ends, in such a
manner as  to have their  extremities in contact in the
middle of the helix, they adhere with more force than
when one is  within and the  other not.
  266.  Place the helix with its axis vertical, and a
small rod of iron or steel within  it.   If it be  now 
168
DAVIS'S  MANUAL.
connected  with the battery,  it may  be raised  from
the table without, the bar falling out; the tendency
of the helix to keep the  bar within  it overpowering
its gravitation.   A small steel bar, merely allowed to
fall through the helix,  while  the current is flowing,
acquires  a  considerable degree  of magnetism.
  267.  If a needle, or a small bar of steel, previously
magnetized, is placed in the helix, in such a position
as to bring its north pole within  the south pole of
the helix, as indicated by the rule in  <§> 264, its  poles
will be  reversed,  the end which  was previously
north becoming  a  south  pole.   When of very hard
steel, and too large in proportion to the power of the
coil, its  magnetism  may merely  be diminished.
  268.  A  small magnetic needle,  suspended  by a
thread near the  helix, will  be drawn within it, its
north pole entering the south end  of  the helix,  or its
south pole the north end.  If the magnet be placed
within the helix, in a contrary direction,  its north
pole entering the north end, it will  be repelled, and
then, revolving without  the  helix,  will  return and
enter by the other  pole.  This effect will take place,
unless the  electro-magnetic power of the coil is suf-
ficient to reverse the poles.   When the needle has
entered with its poles corresponding in direction with
those of the helix,  the  action of the coil tends to
keep it  in the  middle of its length,  though not in
the  line of its  axis.
   269.  A magnetized needle, placed exactly in  the
axis of a vertical helix,  would retain this  situation,
if undisturbed,  being acted  upon  equally  by  the 
               HELIACAL  RING.            169

forces  around  it.   But  it is a  position of  unstable
equilibrium, and if displaced from it in the  slightest
degree, the needle is drawn towards that side of the
coil  which happens to  be  nearest.
  270.  Let a  short  helix,  such as is described in
$271, be laid on a table, with its axis vertical, and a
short and strongly magnetized  needle  of very hard
steel  be  introduced into it with its poles in the  re-
verse direction to  those  of the coil.  If its polarity is
not reversed by the power of the current, it will be
found  to  stand erect in the axis of the helix, being
repelled  equally from  every side,  instead of being
attracted  to every side,  as is stated  in §269  to occur
when  its poles correspond  in  direction  with those
of the coil.
   271. Heliacal Ring. —This is a short helix, con-
sisting of several layers of wire, and  with a  large
                     central opening.   It is  repre-
                     sented at  C, in Fig. 108.  The
                     ends  of the wire are  left free,
                     in order  to  be   inserted  into
                     the  cups  of  the  battery.   At
                     D are shown  two semicircular
                     pieces  of  soft iron,  provided
                     with handles for pulling.   The
                     handles  are  attached  to  the
semicircles,  by ball and  socket  joints,  to  prevent
them  from  being twisted  or wrenched by  irregular
pulling.   When connection  is  made  with  the  bat-
tery, and the  semicircles are passed within  the  coil,
as  shown in the  cut, they adhere  with very consid-
erable force.   The induction of magnetism in these
               15
 
170            davis's  MANUAL.
semicircles,  by means  of the current from a thermo-
electric battery, has  been mentioned in $ 129.
   272.  With thicker  semicircles, such as are  repre-
          Fig. m           sented in Fig. 109, the
                             induced magnetism is
                             sufficient  to  support
                             a hundred weight  or
                             more,  even   with  a
                             small   battery.   The
                             mutual  attraction  be-
                             tween  the semicircles
                             when near each  other,
                             but not in actual con-
                             tact, is comparatively
                             very  feeble.   If  the
                             flow  of   the current
                             in the coil is stopped
                             while they are applied
                             to each other, they still
continue firmly attached; but if once separated, will
not adhere again.
   273. A heliacal  ring, with a smaller central  open-
ing, will sustain a large mass of  tacks or brads  while
the current is flowing  through it, as shown in Fig.
110.   They  adhere together  in rings,  surrounding
each  portion  of  the  circumference, as  the  filings
enclose  the single wire, in Fig. 106.   The  poles of
a magnetic needle  brought near the coil are  attracted
and  repelled as  if  its axis were a  magnet.   An
iron  bar becomes strongly  magnetic when passed
half  way through it.   In  § 185  is  described the
polarity exhibited  by a coil  when it has freedom of
 
HELIACAL  RING.
171
motion.   The polarity of the helix blears so close a
resemblance  to that of a magnet, that  it is  usual to
                       Fig. 110.
speak of it  as  magnetic, and to give the names of
north and south poles to the extremities of its axis.
  274.  In  Fig.  Ill are  represented, at a  a,  two
double cylinders of iron,  enclosing  a coil.   A  sec-
       Fig. ill.       tional view of one of them is
                     given separately at A.   It con-
                     tains a cavity in the form of a
                     hollow cylinder, adapted to re-
                     ceive one half of the coil seen
                     at C, the remaining half pass-
                     ing  into  the  other  cylinder
                     when they are fitted together.
                     A longitudinal opening on one
                     side  of the cylinders allows
                     the wires of the coil  to  pass
                     out.   In this arrangement,  the
                     cylinders  adhere  with  great
                     force when in  contact; but as
                     soon  as  the  current  ceases,
                     their magnetism instantly dis-
 
172
DAVIS'S  MANUAL.
appears, and the adhesion does not continue as  with
the semicircles.   When one of the cylinders is passed
over the coil, the part exterior to  the coil exhibits no
sensible polarity.
  275.  Ribbon  Spiral. — Fig.  112 represents a
strip of sheet  copper,  coiled into  a  spiral.    This
                   c    instrument is  described  here
      Fig- 112.    ^
                       in consequence of its possess-
                       ing considerable magnetizing
                       power, though  its principal
                       uses   will  not be  mentioned
                       till  the   subject of  electro-
                       dynamic  induction comes un-
                       der  consideration,  in   book
III, chapter I.  The  copper  ribbon may be an  inch
wide and  one  hundred  feet long,  the strips being cut
from  a sheet,  and  soldered  together.   Being  then
wound with strips of thin  cotton cloth, it is coiled
upon itself, like the mainspring of a watch ;  instead
of covering it  with cotton, it may be  coiled with a
strip either of cotton or  list intervening.    Two
screw-cups are soldered to the ends of the ribbon;
the internal end, for  convenience,  is  brought  from
the centre, underneath the spiral, to its outside, care
being taken to insure insulation where it passes the
edges of  the ribbon.   The  whole may  be  firmly ce-
mented  together, if desired, by a solution of shellac
in alcohol.
  276.  The spiral  being connected  with the  bat-
tery, its two faces exhibit strong  polarity:  a dipping
needle, placed  on any part of its  surface, or  near it,
will always direct one of its poles  towards the centre,
 
             MAGNETIZING  HELIX.         173

 as seen in the cut, where a dipping needle, N S, is
 represented on the spiral.  On reversing  the battery
 current,  the other pole of the needle  will turn  to-
 wards the centre.  If the spiral is fixed in a vertical
 position, a horizontal magnetic needle  may be used
 with the same  result.   When brought near to one
 side of the coil,  it will be found to direct its  north
 pole  constantly  towards  the centre;  when on the
 other  side, its  south pole.   When  either the  hori-
 zontal or dipping needle is placed  near the outside,
 with its centre of motion  in  the same plane as the
 spiral, neither  pole  will  be  directed  towards the
 centre, but  the magnet  will  place itself at   right
 angles to  the plane  of  the spiral.
   277. The  magnetizing  power of the  spiral may
 be  shown by  connecting  it  with  the  battery, and
 placing a rod of  iron or  steel  in the  central opening,
 or upon it in the direction of a radius, when the iron
 becomes temporarily magnetic, and  the steel perma-
 nently  so.  If  the bar, when  laid  upon the  coil,
 extends across the central  opening,  both  ends will
 become similar  poles, and  the part over  the centre,
 a pole of  the opposite denomination.
  278.  Magnetizing  Helix. — For the  purpose  of
 experimenting on the magnetic power developed by
 the electric current in small bars of  iron  or steel,  a
 helix of the form represented in Fig.  113,  is well
 adapted.   It consists of a number of layers of  wire,
and has a small central opening.   An iron bar passed
 within  it, becomes  strongly  magnetic.   When the
coil  is in a vertical position, the iron bar is sustained
              15* 
174
DAVIS'S  MANUAL.
within it in consequence of the force with which it is
drawn towards the middle  of the coil.   With a large
                battery, a considerable weight  may
                be suspended from the bar, as rep-
                resented in  the cut, and  the whole
                will  be sustained  without any visi-
                ble support.   The helix represented
                in Fig.  107, will lift a smaller rod in
                the same manner.
                  279.  The action of the coil is the
                same, except in amount, as that of a
                single circular turn of the wire.  At
                any two points of the circle  diamet-
                rically  opposite, the  directions of
                the current are also opposite.   Such
                points  may  be  represented  by the
                sections of the wires,  W and W', in
                Fig. 105, the action being precisely
                the  same as  explained  with  refer-
ence  to them.  The  resultant of the forces  exerted
by all the points, tends to  bring  the  centre of the
magnetized bar within the circle.  The action of all
the circles of  which the  helix  is composed, draws
the bar into  it until its  middle lies within the mid-
dle of the helix, in which position only can the forces
neutralize  each other.   The terms axial force and
axial motion are used to designate this peculiar force
and the  motion occasioned by it.
  280.  Axial Bell  Engine. — Fig.  114 represents
an instrument  in which the  axial force  of a  verti-
cal  helix  raises an  iron rod whose centre is below
 
           AXIAL  REVOLVING  BAR.       175

that  of the coil.   This  motion is communicated to
a, hammer,  which strikes  a bell.   A wire,  fixed to
                               the iron  rod below,
                               rests on a spring near
                               B.   When the rod is
                               lifted by the current
                               in  the  coil, C,  its
                               upper end raises the
                               handle of the  ham-
                               mer. A guiding wire,
                               R, keeps the rod ver-
                               tical.  The  circuit is
                               broken at B, by the
                               lifting  of the handle,
                               and is renewed  when
                               the rod  falls.
   281. Axial Revolving Bar. — In the instrument
 represented in Fig.  115,  an iron bar  is suspended
 without visible support by the action of a current
 flowing in the helix  which  surrounds its upper half,
 the bearings above and below serving only as guides.
 The  bar  is made to  rotate  by transmitting  the bat-
 tery  current  through  either  half.   This  mode of
 suspending the rotating bar was first suggested by
 Dr. Boynton.   The screw-cup A, on the stand, con-
 nects with the brass  pillar, and thence with one end
 of the coil.  The other end of the coil dips  into mer-
 cury, contained in a  circular cistern of ivory.  This
 cistern is  supported  below the helix by an arm at-
 tached to the pillar, and has an opening  in  its centre
 to allow the bar to pass through.  A bent wire, pro-
 
176           DAVIS'S  MANUAL.

jecting from the middle of the bar, conveys the cur-
rent  from the  mercury through its upper half to the
                             cud  B.   Some  non-
          flar. 115.              *\       ,  ,   f .  .
                             conductor of electrici-
                             ty, interposed at  I, in-
                             sulates B from the arm
                             which  supports it.  If
                             A and  B are connect-
                             ed  with the battery,
                             and the cistern contains
                             mercury,  the current
                             traverses in succession
                             the helix and the up-
                             per half of  the bar.
                             Since the bar becomes
                             an  electro-magnet  by
the  influence of the coil,  it rotates rapidly on  its
axis, in the same manner as the magnet described in
$ 167.   The cup  C connects with the lower end  of
the  bar,  and, by  uniting  A and C with  the battery,
the  current traverses the lower  half, also producing
rotation.
   282,  In Silliman's Journal  for March, 1847, will be
found a figure and description of a similar instrument.
contrived by  Dr.  Page, in which no mercurial con-
nections are used.   The bar is  sustained without
visible support, as in Fig. 115,  and the current  is
conveyed by a wire  tipped with  silver, which  plays
upon a silver ferule  on  the middle  of the  bar.
   283.  Inclined   Revolving  Bar. — This instru-
ment,  represented in Fig. 116, is designed to  show
 
INCLINED  REVOLVING  BAR.     177
the change produced in the direction of rotation by
altering the course of the current.   The  helix, which
                          surrounds the lower end
                          of the  bar, is represented
                          in section, in order to show
                          a wide glass  tube within,
                          which  can be filled  with
                          mercury.   The iron bar
                          rests in an  agate  cup at
                          the bottom  of the tube.
                          Its  upper  end  connects
                          with a  brass  cup on an
                          ivory arm proceeding from
the upright brass pillar.   This cup may be united by
a bent wire with a similar one on the pillar, as  rep-
resented in  the cut.  When  the  screw-cups on the
base board are connected with a battery, the current
passes  from one of the  cups up the pillar and along
the  bent  wire  at  the  top; thence  it passes  down
the inclined  bar.  A little mercury in the glass tube
conveys the current to the brass at the bottom of the
tube.  It  then passes through the helix  to the other
screw-cup.  The bar now rotates on its  axis; a cir-
cular card attached to it renders the motion percep-
tible at some distance.
  284.  The course of  the  current is changed by re-
moving the wire at the  top of the pillar, and, having
filled the  glass  tube with  mercury, dipping into it
another bent wire, fixed by a binding-screw to the
middle  of the pillar.   The inclined position of the
bar is adopted to prevent this wire from accidentally 
178
DAVIS'S  MANUAL .
obstructing its movement.  Only the lower part of the
bar is now  traversed by the current,  which divides
itself between that and  the mercury.   A rotation of
the bar in the opposite direction is thus obtained.
  285.  Inclined  Bar  revolving  round  Conduc-
tor.— The  instrument  represented in Fig. 117  is
                           similar  to  the  one last
                           described, except that the
                           inclined bar  of iron re-
                           volves  round  a vertical
                           copper  wire, which con-
                           veys the current from the
                           mercury to the pillar, with
                           which it is connected by
                           a  brass  arm.   The  iron
                           bar  rotates on  its axis in
                           the  opposite direction to
that of its revolution around the wire.  A revolution
of the mercury may also  be observed in  the  same
direction  as that of  the  iron around the wire.  The
glass  tube requires  to be  nearly full  of mercury to
produce contact  with the vertical  conducting  wire,
which enters a  short distance  only within-it.  An
ivory ring,  surrounding  the wire, insulates  the little
arm by which  the  bar  is sustained  in its inclined
position, so that the current does  not traverse the
upper part of the bar.  When enough  of the mercury
is  removed  to  interrupt  contact between  itself and
the vertical  wire, and the bent wire is  inserted  so as
to convey the current from the middle of the pillar,
the iron rod changes the  direction of its motion.
 
AXIAL  REVOLVING  CIRCLE.      179
Fig. ISP.
  286.  A short  iron  rod, placed in the  glass tube
instead  of  the inclined  bar, floats  in the  mercury.
When the  current  is  passed  through  the vertical
wire, the rod is drawn down into the tube, and  re-
volves around  the  wire  and on its axis.   By cov-
ering the rod with sealing-wax, it no longer conveys
any  part of  the current, but  is  carried round by the
rotation of the mercury.   If the  vertical  wire  is so
arranged as  to have freedom of motion, it revolves
in the same direction as the iron bar, the  two keeping
opposite, and  moving  round a common centre.
  287.  Axial  Revolving  Circle.—By employing
two  curved  helices, the axial motion of an iron bar
                               may  be  converted
                               into a  direct  rota-
                               tion.  In Fig. 118
                               is  seen  a  revolv-
                               ing circle, composed
                               of  two  semicircular
                               bars, the shaded one
                               of  iron, the  other
                               of  brass.   This cir-
                               cle is supported  by
                               four  grooved  fric-
tion  rollers,  so as to  move  freely  within the two
coils.  Its circumference is cut  into teeth, and its mo-
tion  is communicated to two smaller toothed wheels,
on the  axis  of one  of which  is  the  break-piece.
When the  current  passes,  one of  the  helices  be-
comes charged, and draws  the iron bar within  it.
As soon  as  its centre reaches that of the coil, the
 
180           DAVIS'S  MANUAL.
Fig. U9.
current  is interrupted ;  and, as it moves on  by its
acquired momentum, the action of the  break-piece
causes the other helix to be charged,  and the  iron
to be drawn into  it.
  288.  Vibrating Helix. —Instead of a jar moving
within the helix,  the  latter may be made to move
                             over  the  bar.   In the
                             instrument represented
                             in  Fig.  119,  there  is
                             a  curved bar of  iron
                             of the U form, and the
                             helix is  so suspended
                             as  to pass  along  one
                             of  its poles.    When
                             the  coil hangs  freely,
                             one  of  its ends  dips
                             into a mercury cup on
                             the brass pillar.   The
action of the  current makes the  iron an  electro-
magnet, and  the  helix  passes  along over the  pole.
This motion lifts the wire out of the mercury, which
breaks  the  circuit,  and the helix falls back.   The
instrument is similar in principle to the one described
in <§> 187, except that an  electro-magnet  is employed
instead of a steel  magnet.
   289.  In place of a  straight iron  bar moving with-
in  a helix, a  bar having  the  form of the letter U
may be employed with two coils placed side by side.
In Fig. 120, C C are the two helices, secured together
 by a brass clamp, not  represented ;  and M is the bent
 iron  bar.  Suppose the bar to  be resting on  a  table
 
DOUBLE  AXIAL  BELL   ENGINE.   181
in the position indicated by the dotted  lines in the
cut, with its poles within the double helix, which is
                     Fig. 120.
raised a little from the table.   When  the battery
connections are made, the bar instantly rises until its
bend reaches the helices.   The movement is more
powerful than that of a straight bar.
  290.  Double Axial  Bell Engine. — In the in-
strument represented in  Fig.  121, motion is  produced
           p^ 121             in  the manner just
       a                       described.  The force
     j=§r                      with which the  bar
                               is drawn up   is in-
                               creased by its attrac-
                               tion  for  a straight
                               armature fixed above
                               the coils.   The bent
                               bar, becoming an e-
                               lectro-magnet, moves
                               towards the armature,
                               as  the latter   would
do, if free to move, towards a  fixed magnet.  Near
B is a break-piece, so  arranged that  the  current  is
interrupted  when the  bend of the bar reaches the
helices, causing it to fall back.   As the electro-mag-
net rises, it communicates motion to a  hammer which
strikes the bell
                 16
 
182
D AVIS ' S  MANUAL.
  291.  Upright Axial Engine. — In the instrument
represented in  Fig. ^ 122,  the alternating movement
          _,.   ,„           of two bent bars is con-
          Fig. 122.
                           veyed by  cranks to a
                           balance-wheel above the
                           helices.  As the wheel
                           revolves, the current is
                           conveyed to each double
                           helix in succession, by
                           means of a break-piece
                           on its axis.  This is sim-
                           ilar  in  construction  to
                           that described in § 187,
                           except  that  the  two
                       "^ wires  which  press on
the break-piece are connected  respectively with one
end of each double coil, while their other ends both
connect with the axis.
  292.  Horizontal Axial Engine.—In the instru-
ment represented in Fig. 123, the two double helices
                          Fig. 123.
are fixed horizontally in the same line.  The iron bars 
       SINGLE  BEAM  AXIAL  ENGINE.    183

are  connected at their  lends by  a transverse  bar,
through the ends of which pass guiding rods.  These
slide in the  tops  of the small pillars, and keep the
bent bars  in  place.  On the shaft  of the  balance-
wheel  is the  break-piece.
  293.  Double  Beam Axial  Engine. — An instru-
ment in which there are two horizontal beams,  each
                     Fig. 124.
C3p                                    £3p
connected with  a bent bar moving in an  upright
double helix, is represented  in Fig. 124.  The mo-
tion  of the beams is communicated to a single fly-
wheel, by means of toothed wheels moved by cranks.
  294. Single  Beam  Axial  Engine. — Fig. 125
represents an  instrument  in which  a  reciprocat-
ing motion is communicated to a horizontal beam.
by the alternate  movement of two bent bars.   The
iron  bars are  not attached to the ends of the beam,
but  simply  rest  upon  them.   When  the  current
passes, one of the bars is lifted, and the weight  of 
184           DAVIS'S  MANUAL.

the other depresses  that extremity  of  the  beam on
which it rests. There is a break-piece of peculiar con-

                      Fig.  125.
struction at B,  by means of  which  the  current  is
alternately  transmitted to each of the  double helices.
To Dr. Page is due the invention of the first instru-
ments in which the source of motion was the  axial
force exerted  by  helices on either straight or bent
bars  of iron.
   295.  Electko-Magnet.—A bar of  iron,  wound
with insulated wire,  so  as  to  be enclosed in a he-
     „.  ,n„      lix, is termed an Electro-Magnet.
     rig". 126.
                  During the passage of an electric
                  current along the wire, the bar
                  exhibits a  remarkable  degree of
                  magnetic  power,  far superior  to
                  that  of a  steel  magnet  of the
                  same size.  In all the instruments
                  in which a current is transmitted
                  through a coil surrounding an iron
bar, the iron becomes  temporarily an  electro-magnet.
 
      ELECTRO-MAGNET,  IN  FRAME.   185

For the  purpose of showing its lifting power, the
electro-magnet is made of the U form, (Fig.  126.)
The battery with which it is used should be in pro-
portion to the length and fineness of  the  wire,  in
order  to  obtain  the  greatest power.   With a  thick
and rather short wire, a battery of one or two pairs
will be  preferable.    With a long and fine wire, a
number of pairs  should  be employed.  A small elec-
tro-magnet will sustain  a  large  mass of iron nails  or
filings about its  poles, which fall when the flow of
the current is  stopped.
  296. Electro-Magnet, in  Frame. — Fig.  127
                     Fig.  127.
represents an electro-magnet, fixed in a frame, for the
            16* 
186
DAVIS'S  MANUAL.
 purpose of supporting heavy weights.  The  arma-
 ture, A,  consists of  a  semicircular  piece of iron.
 With the electro-magnet, this form is preferable to a
 straight bar.  If the iron  of the  magnet is soft and
 pure, its magnetic power  is  immediately  communi-
 cated and lost, according as the  connection with the
 battery  is made or broken.   When,  however,  the
 armature is applied to the  poles, and the flow of the
 current stopped while it is attached, it will continue
 to adhere for weeks or months with great force, so as
 to be able to sustain one third or one  half as much
 weight as while the current was circulating.  But if
 the  keeper be once removed, nearly the whole  mag-
 netism  disappears, and the magnet, if  of good iron,
 will not even be able  to lift an ounce.  The purest
 iron retains, for  a time, a certain amount of  mag-
 netic power, after being  strongly magnetized, even
 when  an armature  is not  applied.  This amount
 increases  with  the size  of the bar.
  297.  The poles  of the  magnet  are, of course,
reversed by changing the  direction  of  the current.
 When  the change is  made rapidly, while the  arma-
ture is applied, it does not fall off.   If a considerable
weight  is suspended from it,  it may fall a very slight
distance, and be attracted again.   The time required
to destroy the  previously  existing polarity, and  to
renew  it  in  the  opposite  direction, is  exceedingly
short.
  298.  Electro-Magnet,   in Case.—An electro-
magnet of considerable power is  represented in Fig.
128, fixed horizontally in a case.    The poles project 
     POWER  OF  ELECTRO-MAG NETS.  187

from one  end, and  a  semicircular  armature may be
applied to them, as in the cut.   At the other end of
                     Fig. 128.
the case are seen two screw-cups, for making con-
nection with  the battery.   There are two strong
rings, one attached  to the bend  of the magnet, and
the other  to  the  armature.   The  magnet, with  its
case,  may be  suspended by the  former ring and
weights hung from the latter.
  299. Very large electro-magnets have  been made
to lift 3000 lbs.   The proportion of the power to the
weight of the bar  increases as their size is diminished,
up  to a certain limit ;  and a small electro-magnet
may be made  to  sustain 400 or 500 times  its own
weight, excluding that  of the coil.   Increasing the
battery current does not increase the magnetism in-
definitely.  Small bars  acquire  their full power, or
become saturated with  magnetism, with  a moderate
battery.  A current from the thermo-electric battery
(Fig. 11),  when  transmitted through the wires  of
an electro-magnet, induces a considerable charge  of
magnetism.
  300.  An electro-magnet,  like the  steel  magnet, 
188           DAVIS'S  MANUAL.
exerts its attractive force through  intervening sub-
stances ;  and the  phenomena are more striking with
the former, in consequence of its  greater power.   It
will often be able to  lift  its armature, with a plate
of glass interposed ; and when  a few thicknesses of
paper only intervene, a considerable additional weight
will be supported.
   301.  Electro-Magnet, with  Three Poles. —
This  instrument, represented  in  Fig. 129, consists
        Fi«: 129.        °f an  iron r0^> wound with
                       insulated   wire,  which  is
                       carried  in  one   direction
                       around half the  length of
                       the rod, and then turns and
                       is wound  in the other di-
                       rection.  The effect of this
                       arrangement is, that, when
                       connection is made with the
                       battery by  means  of the
screw-cups on the stand, the two extremities of the
bar become similar poles, while the middle acquires
a polarity opposite to  that of the ends.  The middle,
as well as the ends, will sustain a considerable weight
of iron.   By reversing the  direction of the current,
all the poles are reversed.  The arrangement of the
poles may be shown by passing a  magnetic needle
along the bar.
   302.  Communication of Magnetism  to Steel by
the Electro-Magnet. — The great power possessed
by the electro-magnet renders  it peculiarly fitted for
inducing magnetism  in steel;  hence it  is very con-
 
        STEEL  MAGNETS  CHARGED.    189

venient  for charging  permanent magnets.  A short
steel bar,  if applied like  an armature  to the poles
of an electro-magnet of the  U form,  will become
strongly magnetic,  the end which was in contact
with the  north pole acquiring south  polarity.   A
longer bar may be charged, by  employing the same
process that has been described in $ 251,  for touching
by steel magnets.
  303.  Bars  of the  U  form are most readily mag-
netized  by drawing  them  from  the bend  to the
extremities across the poles  of the U-electro-magnet,
in such  a  way that  both halves of  the bar may pass
at the same time over the poles to which they are
applied.    This  should be  repeated several  times,
recollecting always  to  draw the  bar in  the same
direction.   Then, if it has a considerable thickness,
turn  it in  the hand, and repeat the process with its
opposite surface,  keeping each half applied  to the
same pole, as before.   In Fig. 130, the arrow indi-
cates the direction in which the motion should take
place.   Of  course,  the result  will be  the  same, if
the steel  bar is  kept stationary,  and the  poles of 
190
D A VI S ' S  M ANUAL .
the electro-magnet are  passed  over  it  in  the re-
verse  direction.
  304.  In order to remove the magnetism of a steel
magnet  of the U form, it is only necessary to reverse
the process; that is, to place one of its poles on each
pole of  the electro-magnet, and draw it over them in
the opposite direction to that of  the arrow in Fig.
130.  In  this  way, the  magnet  may be  so com-
pletely discharged, as to be unable to lift more than
a few iron filings.
  305.  A bar magnet may be deprived  of its mag-
netism,  in a great degree, by passing the north pole
of an electro-magnet over it,  from its south pole to
its middle, and then lifting it off perpendicularly ;  if,
then,  the south pole  be passed in the same manner
over the other extremity of the steel bar, it will  be
found to  have lost the  greater part of  its  polarity.
If necessary,  this process may be  repeated  several
times.  A still more effectual  mode is to make use
of two  electro-magnets;  place the north  pole of one
on  one end of the bar,  and the south  pole of the
other on its  other  extremity, and  draw the  poles
along the bar till  they meet at its middle;  then lift
them off perpendicularly.
   306.  The  electro-magnet  described  in <§> 298  is
very  convenient  both for communicating  and  re-
moving magnetism.  On account of its  power, bars
of considerable size may be fully  charged by it.  If
the steel  magnet  has not the  same, or nearly the
same, width, from pole to pole, as  the electro-magnet,,
it can be charged by drawing each half separately 
MAGNETOMETER.
191
over the proper pole of the electro-magnet, in  the
manner  described in § 251, for bar magnets.
  307.  Magnetometer. — A  simple  application of
the electro-magnet brings us at once to a very useful
instrument, the Magnetometer,  represented in Fig.
131.  Its  use  is to measure the magnetizing  power
of galvanic currents.   The  form in which it is now
described  is new.   It  consists of  a  vertical electro-
magnet, of the U form, with  an armature above it,
attached to the short arm of a balanced lever.  The
long arm of the lever is graduated decimally to meas-
ure, by means  of weights of from  100 grs. to 10,000
grs., the force  required to detach the armature from
the electro-magnet when connected with the battery
whose power is to be determined.  The lever is sup-
ported  on an axis with knife-edge  bearings.   The
armature may also be  suspended on knife  edges at-
tached  to the beam.   On  the under surface of the
armature is  brazed  a thin  plate of brass, to  prevent
its adhesion  to the poles.   A difference of magnetiz-
ing power of 10 grs.  can  be estimated in  a series
extending from 100 grs. to more than 100,000 grs.,
or the limit  of saturation of the magnet.   Two sets 
192           D A V I S ' S  MANUAL.

of screw-cups will be seen on the board; one of these
is connected with a short coil round the magnet, the
other with a long coil.   By making this long coil of
fine wire, the instrument compares currents differing
in their intensity.  Two batteries are first estimated,
as to quantity, by their magnetizing power  through
the short coil.  Their relative intensity is then shown.
compared with  their quantity, by  their magnetizing
power through the long coil,  their intensity being in
mathematical proportion  to the conducting power of
the  wire for each,  and therefore to the  amount of
electricity which passes.   In comparing  the power
of different batteries, — a matter now  of  some prac-
tical importance, — this instrument gives a rapid and
uniform result.
  308.  Instead  of  using a  long coil  of wire, sur-
rounding the  magnet, in  estimating  intensity, the
current  may be passed through a  detached coil of
fine wire, and through the short coil  of  the instru-
ment, which would give a similar result.
  309.  Axial  Magnetometer. — Another  form of
                     Fig. 132.
the magnetometer  is represented in Fig.  132.   In
this, the axial  attraction of a double helix is made 
    ELECTRO-MAGNETIC  TELEGRAPH.  193

use of, as in the Axial Galvanometer invented by Dr.
Page, and described in  Silliman's Journal,  vol. xlix.
p.  136.  In other  respects,  the  construction  is en-
tirely different  from his.   A.  double coil  of  fine wire
may be added, as in  Fig. 131, to compare intensity
currents.
   310.  Electro-magnetic  Telegraph. — Within a
few years, the  electric telegraph, the most important
application of  galvanism  ever  made, has been con-
trived and  brought  into  practical  use.   A  slight
sketch of  the history  of this invention, drawn partly
from  Vail's  book, " The American Electro-Magnetic
Telegraph,"  and  partly from  the original sources.
will  be of  interest here  as  an  introduction.   This
is the more needed, as there has been  great  confu-
sion as to the  originators and  inventors of the tele-
graph.  We  find  that  the  first  electrical telegraphs
were put in operation by Lomond, in 1787 ; by Rei-
zen, in 1794 ; and by Salva  and  Belancourt, in 1798.
In these,  the common electrical machine  was used,
with  which, of course, no important result could be
obtained.   In  1809, Soemmering laid the foundation
of the galvanic telegraph,  by  proposing to employ,
with  the  Voltaic pile, a wire for every letter in  the
alphabet,  terminating in gold pins inserted  in a glass
cell containing water, the letters being  indicated by
the evolution of oxygen and hydrogen from the pins.
A similar plan  was proposed by Dr. Coxe, of Phila-
delphia, in 1816.   In  the same year, the  use of
machine  electricity for the telegraph, was revived
by Ronalds, in England.
               17 
194
DAVIS'S  MANUAI
  311.  On  the discovery  of electro-magnetism,  in
1819, Ampere very early proposed the  deflection of
the needle in place of the decomposition of water
for  indicating the  passage  of the current.   In the
treatise  on new discoveries in electricity, by Ampere
and Babinet, published  in  Paris, in 1822, the tele-
graph of Wheatstone is  anticipated by fifteen years,
in all essential  details,  with  the exception  of the
greater  number of  wires  required  in the  former.
Here it  is necessary to draw a line between the pro-
posers and introducers of an invention.  The claim
of originality belongs to  the former, but public grati-
tude is usually accorded to the latter.   The deflection
of the  needle  for  telegraphic  purposes was subse-
quently referred to  by many  other writers;  but  it
seems first to have  been introduced into practice by
Schilling, in Russia, at  the end of 1832 ;  by Gauss
and Weber,  at  Gottingen,  in  1833;  in Vienna,  in
1836; and,  finally,  on a large  scale, by Wheatstone,
in England,  and by  Steinheil,  at  Munich, in  1837,
or soon  after.   The  credit of the construction of the
galvanic telegraph  belongs  thus to Schilling, Stein-
heil, and  Wheatstone, by the latter of whom, with
some of his  English coadjutors, many of the practical
difficulties in the modes of transmitting the current
were overcome.  The  invention of Grove's battery
was also an  important era in the introduction of the
telegraph.
  312.  We come now to the electro-magnetic tele-
graph, which, in its beautiful simplicity and efficien-
cy, surpasses all others yet  introduced into practice. 
   ELECTRO-MAGNETIC  TELEGRAPH.  195

Barlow, in England, seems to have made some early
suggestion of this kind ;  but it was  not until 1830,
on the  construction of  the  first  powerful electro-
magnets, by  Professor Henry, of Princeton,  N. J.,
that  this form of  telegraph became possible;  and in
his  first  paper on the  results  of  these  experiments,
in some of which long wires were used, he at once
applies  the new  facts  to  the telegraph.   The  pres-
ent form of the  American telegraph is claimed to
have been suggested in 1832,  by Dr. C. T. Jackson,
and by Professor Morse.   It was finally  matured by
Professor  Morse,  and  introduced  by him between
Baltimore and  Washington, in 1844, after a delay
before  Congress of more  than  six years.
  313.  Electro-magnetic Telegraph. — Fig. 133
represents lae recording  part  of the telegraph.   It

                      Fig. 133.
consists of an electro-magnet,  armature, and lever,
arranged in a similar manner to  the  magnetometer,
(Fig.  131.)  At  the extremity of  the lever is a blunt
point, which marks the strip of paper when the elec-
tro-magnet is in action.   If one wire from the battery
is  placed in  one of  the screw-cups, whenever the
other wire is touched to the remaining cup, the arma- 
196           DAVIS'S  MANUAL.

ture  is powerfully attracted  by the magnet, and  the
point on the lever presses the  paper  into the corre-
sponding groove of the roller, so that lines or dots are
made according to the time during which the contact
with the battery is maintained, the paper being slowly
drawn under the roller.
  314.  The following table exhibits the signs em-
ployed by  Professor Morse: —

       MORSE'S  TELEGRAPHIC  ALPHABET.
NUMERALS.
  It will be observed, that the  characters are formed
by  different combinations  of dots, and of  short and
long  lines, with  short  and long  spaces.   Between
each letter of a word, a short space is used, and long
ones between  the words themselves.   Sentences are
separated  by still  longer spaces.
ALPHABET.	n---
a---	o - -
b--------	p ---
c - - -	q---
d----	r - -
e -	s----
/----	t —
g-----	u----
h----	V---
i - -	w---
j------	X----
k-----	y --
I	
m----	4' - -
 
CLOCK-WORK  TELEGRAPH.     197
  315.  Telegraph,  with Clock-work.__In Fig.
134, the telegraph is shown with all  the appendages
                     Fig. 134.
usually employed.  The electro-magnet near A, and
the lever, are  the  same  as  in  the instrument last
described;  connected  with  them  is an  apparatus,
moved by clock-work, for carrying the paper, which
is unwound  from a  large spool,  S,  by the  rollers
between which it passes, and  thus drawn slowly over
the registering point.  The  first  movement  of the
lever sets the clock-work  in action, and a break and
friction-wheel are sometimes added, by which it  is
stopped shortly  after the  signals cease to be trans-
mitted.   A  bell, seen at  B,  is  connected with the
lever  so that the first motion communicated  by the
battery gives a  signal to  the attendant.
  316. The  battery used in  operating Morse's tele-
              17* 
198
D AVI S ' S  MANUAL.
graph, is a modified form of Grove's, (§ 45.)  Instead
of a galvanic series,  the magneto-electric machine,
to be described hereafter, has  been used as a source
of electrical  power for working the telegraph.   The
first instance, it is believed,  in which this was accom-
plished with Morse's telegraph, is given below, as an
example of telegraphic writing, taken from the scroll
used on that occasion: —
 II"         r       i      t      t     e      n

  b          y        t        h      e       p

o        w        e       r          o        f

o       n      e        o        f           D
a          v         i        s        e        s

 M         a         g           net
o
t            Elect

r       i       c           Mac

hines             B

        s       t       o        n           D

      c         r            9              1

  8           4            4 
                  signal  key.              199

   317.  Signal Key. — Fig. 135 represents the in-
 strument usually employed to make the various con-
            Fig. 135.            tacts, differing in suc-
                               cession  and  length,
                               by which the system
                               of lines and dots, rep-
                               resenting the various
                               letters, are produced
                               at the  other end of
                               the  telegraph.   The
 ■S)                        <v>  fingers  are  shown
 resting  upon a  knob,  attached  to a metallic spring,
 by the  depression of which contact is made with a
 metallic conductor on the baseboard,  connected with
 a  screw-cup at  one extremity  of  the  instrument;
 the other screw-cup is connected with  the  spring.
 One battery wire  passes  into  the  first  screw-cup.
 The other screw-cup receives one of the wires of the
 telegraph, which proceeds to the registering apparatus
 at the other station.  By the  other  telegraph  wire,
 the remaining  extremities of the battery and of the
 registering  apparatus are  directly  connected.  The
 circuit is therefore completed by depressing the key,
 and is immediately broken by the action of the spring
 when the fingers are removed.
   318.  Instead of using  the  second wire  directly
connecting  the  battery  and register,  the earth is
sometimes employed as a conductor, by  connecting
the pole of the battery and register with a large me-
tallic plate, sunk in the ground at each terminus of
the telegraph.   In this case, the number of wires
needed  is reduced to one.
 
200
DA VIS'S  MANUAL.
   319.  The wires are well insulated, and are carried
from  station to station along high  posts, about  300
feet apart.   On some of the lines they are of copper;
on others, of iron.   An iron wire is  much inferior in
conducting  power to a copper one of the same size :
but  the  greater   cheapness admits of the use  of
much  thicker  wires.  These are found to convey
the current well, and are less liable to be broken than
the copper wires.
   320.  The number of  galvanic pairs required to
work the telegraph  varies with  the  distance  and
consequent  length of the wires.  From twelve to
thirty  or  fifty  have  been  employed upon different
lines.  The  largest number  would still be inadequate
to give sufficient power to the electro-magnet at very
long distances,  wrere it not  for the invention of the
receiving magnet, by Professor  Morse.  An electro-
magnet of the  most sensitive construction  is placed
at the end of the telegraphic line, which moves an
armature by the  galvanic  power, sufficiently  only
to make contact between a platinum point and  sur-
face, which  are in the circuit of another small  bat-
tery, immediately on the  spot.  This  at once works
the registering apparatus with  great force,  its cur-
rent having  to  traverse only a few feet of wire in its
passage to the  registering electro-magnet.
   321. Axial  Receiving  Magnet.—In Fig.  136
is represented  a  receiving  magnet  of a new  con-
struction.   The movement  is produced  by the axial
force, an iron bar of the U form being  drawn within
a double helix,  as described  in $ 289.  The bent bar 
AXIAL  RECEIVING  MAGNET.     201
is horizontal, but is so suspended that its own weight
withdraws it from the coils  when the  current  is
interrupted.  In  the  cut, the  instrument is shown
in  connection with a local  battery for  igniting an
explosive  charge in blasting rocks,  or for submarine
or  other  explosions.   The  loss  of power  by con-

                      ing-. 136.
duction,  renders it difficult, with  a moderate  sized
battery, to  explode the charge by  heating a wire at
a considerable  distance.   In  the arrangement  here
described, the receiving apparatus is used to complete
the circuit  of a small battery in a  protected position
near the place  where  the explosion is to  occur. 
202
D AVIS ' S  MANUAL.
  322.  In the figure, the coils are placed horizon-
tally, and the  U-shaped iron bar, which moves in
connection with a vertical bar, suspended by an axis
above,  enters  them  at  M.   The influence  of  the
helices is aided by an armature, as in Fig. 121.  The
connections of the  single galvanic pair, seen in  the
foreground, are so made  that its circuit is completed
whenever the vertical bar comes in contact with the
platinum point, A, immediately in front  of it.  This
takes place as soon  as  the long battery circuit is
completed  by  the  operator  at  a distance, and  the
axial magnet drawn into the coils.  This instrument,
even without the armature, is  more  sensitive than
the  receiving magnet of Professor Morse, and may
be  used with  some advantage  as a receiving appa-
ratus for  the telegraph.
  323.  Axial Telegraph. — Fig.  137 represents a
form of telegraph in which the axial force is used,
                           motion being obtained in
                           the  manner  described in
                           $ 289.  This is introduc-
                           ed as a  new instrument,
                           and its originality is here
                           claimed.   Two  upright
                           coils,  C, are  supported  a
                           short  distance above the
 baseboard.   Entering these from below is a U-shaped
 rod of  soft iron,  fitted to be drawn up into the coils,
 under the influence of the  galvanic current.   When
 not thus drawn  up,  it  rests on a spring,  shown  in
 the cut, by  which the  instrument is rendered more
 
     CLOCK-WORK  AXIAL  TELEGRAPH. '^Cl

sensitive.   A  grooved roller, for carrying  the paper,
is seen above  the coils.   To the iron bar  is attached
a blunt  point, so as to project above  its poles, in the
centre, and in opposition to the groove on the roller.
Contact being made  with the battery, the soft iron
rises up within the coils, and marks  the paper.  On
the whole, this form of telegraph is more sensitive
and efficient than the  electro-magnetic, and less liable
to derangement; from the absence of the  lever, it  is
also more compact.   A small armature may be placed
across the coils above, as described in $ 290, by which
the mark is made with still greater force; but in this
case, the motion  is partly electro-magnetic.
  324.  Axial  Telegraph,  with  Clock-work. —
In Fig.  138, the axial telegraph is represented, with
                     Fig. 138.
clock-work annexed, for  carrying  the  paper, in the
manner already described  in  connection  with the
electro-magnetic telegraph.   The coils of  the  axial 
204           da vis's  manual.

apparatus are partly seen at  M.   The large scroll of
paper is shown at S, with the strip, P P, proceeding
from it.   The  arrangement  for giving the alarm by
the bell, B, is  also annexed.
  325.  Axial  Telegraph,  with Engine.—A dif-
ferent arrangement of the  telegraph is shown in Fig.
139. where the machinery for carrying  the paper is
                     Fig. 130.
moved  by an axial engine, driven by a  small local
battery, and set in action, if desirable, by the com-
pletion  of the circuit of  the  telegraph.   The soft
iron bar of the  telegraphic apparatus is  seen at A.
and  that of the engine at M.   There is a peculiar
arrangement  added for commencing and  suspending
the action  of the engine when the telegraph  begins
and  ceases to work.
  326.  The  deflection of the gold leaf galvanoscope. 
    reciprocating  armature  engine.  205

(Fig. 63), has recently been proposed as a means of
telegraphic indication.   The extreme  delicacy of this
instrument enables  it to give  a result with a single
pair of plates through great  lengths of wire.   There
are  no  means,  however,  of  recording  its  action,
which  would also  be seriously  interfered  with by
the influence  of atmospheric electricity on  the  con-
ducting wire.  The transmission of the battery cur-
rent through the telegraphic wire, however long, is
practically instantaneous.  Experiments which have
been made  on the  velocity of electricity, appear to
indicate  that  it  is  considerably  greater than  that
of light, which travels  nearly  200,000  miles  in  a
second of time.
  327.  Reciprocating  Armature  Engine. — In this
instrument,  contrived by Dr. Page, two electro-mag-
nets of the U form, represented at M M  (Fig. 140),
                     Fig. 140.
are  firmly secured  in a vertical position, the  four
poles  appearing just above  a small wooden table.
The two armatures, A A, connected by  a brass bar,
              18 
206
davis's  manual.
move upon a horizontal axis in such a manner that
while one  is  approaching the poles of the  magnet
over which it is placed, the other is receding from
those of the  other  magnet.  The brass bar is con-
nected with one extremity of a horizontal beam, the
other end of which communicates motion by means
of a crank to  a fly-wheel.  On the axis of the fly-
wheel at B is the break-piece.   Each magnet being
charged  in  succession,  the armatures  are  attracted
alternately, communicating a rapid reciprocating mo-
tion to  the beam, and  consequently a  rotatory one
to the  fly-wheel.
  328.  Horizontal Reciprocating  Engine.—Two
electro-magnets of the U form, M M (Fig. 141), are
supported in  a horizontal  position,  with a  single
armature  A  fitted  to  vibrate horizontally between
them.   When the battery connections are made with
the screw-cups on the baseboard, one of the magnets
will be  charged, provided the break-piece is in such
a position with regard to the springs as to complete
the circuit.   The  armature  will  now  be attracted
towards the charged  poles.  Just before it reach*»-= 
revolving  armature.       207
Fig. 142.
them, the  movement of  the  break-piece interrupts
the current in the magnet, destroying its polarity,
and then causes the current to be transmitted through
the opposite one;  this becomes charged in its turn,
and attracts the iron bar, A, which imparts  motion
to the balance-wheel, W.   By means of clock-work,
the rotation of the wheel  causes a hammer to strike
the bell placed over one of the electro-magnets.
   329.  Revolving Armature. — In this instrument,
invented by Dr. Page, a small bar of iron is arranged
to revolve horizontally just above the poles of an
electro-magnet of  the U form, fixed in a vertical  po-
sition, as seen in Fig. 142, where A is the iron bar,
                   and  M the electro-magnet.   To
                   the axis of motion of the bar is
                   affixed a break-piece, made by
                    filing  away  two  opposite sides
                    of a small solid cylinder of silver.
                    Upon the narrow prominent por-
                    tions  thus left, play two silver
                    springs, shown at W in  the cut,
                    opposite to each  other.  One of
                    these springs is  connected with
                    a screw-cup on  the  stand; the
                    other communicates with one ex-
                    tremity of the wire enveloping
                    the electro-magnet, the other end
                    of this wire  being fixed  to a sec-
                    ond cup on the baseboard.  The
                     break-piece  is so arranged as  to
 release  the  springs  from their  bearing just as the
 
208           davis's  MANUAL.
armature passes over the  poles; and to restore them
to it  again  when  it has moved on somewhat more
than  a  quarter of a  circle, so as  to be  a little in-
clined from a position  at right angles to the plane
of the magnet.
   330.  On  placing the  bar in this position, and con-
necting the cups  on the stand with  a battery,  the
electro-magnet becomes charged,  and consequently
attracts the armature  towards its poles:  as soon as it
reaches their plane,  the springs leave the projecting
parts  of the break-piece, and the  current is cut  off.
The polarity of the magnet is  now destroyed, and it
ceases to  attract  the armature, which moves on by
the momentum it has acquired, until it passes a little
beyond a  position at right angles to the plane of the
magnet.   At  this point,  the springs again come in
contact with  the  break-piece,  and  the flow of the
current is  renewed.   The attraction now exerted by
the poles  gives a new impulse to  the armature,  and
the circuit being again  broken  when it reaches their
plane, it continues its motion in the same direction,
revolving  with great speed.   Care should be taken
that the springs are  in  such a  state of tension as to
open  and  close the  circuit at  the  proper points, as
indicated in the above  description.  The motion of
the bar is not reversed  by  changing the direction
of the current.
   331.  Revolving Armature  Engine.—In this in-
strument there are  several  armatures  fixed  on  the
circumference  of a vertical wheel,  parallel to its axis.
In  Fig. 143  three  are represented,  each  of them 
     REVOLVING  armature  engine.   209

marked A.  On the poles of the electro-magnet, M,
is  secured a brass  plate, from which rise two pillars
to support the axis of the wheel: as the wheel turns,
the iron bars pass  in succession over  the poles with
their extremities very near to them.   At B, on the
shaft of the wheel, but  not insulated  from it, is the
break-piece, consisting of a small  metallic disc, from
which project, in a lateral direction, several pins, equal
                    in  number to the iron bars; or
                    the disc may be furnished with
                    a corresponding number of teeth.
                    A silver spring connected with
                    one end of the wire surrounding
                    the electro-magnet,  plays  upon
                    these  pins or teeth; the  other
                    end of this wire is soldered to
                    the iron of the  magnet, which
                    brings it into metallic  commu-
                    nication with the shaft by means
                    of  the  brass  plate and  pillars.
                    Or  the wire may be terminated
                    by a second spring pressing upon
                    a cylindrical part of the axis.
                       332.  The break-piece is ar-
                    ranged in such a manner, that the
                    electro-magnet is charged  when
any one of the iron bars is brought near it by the mo-
tion of  the wheel.   This bar is then attracted towards
the poles; when it arrives at the plane of the mag-
net, the current is cut off, in consequence of the cor-
responding  pin or tooth releasing the  silver spring
               18*
 
210
davis's  manual.
from  its bearing.   The armature  being  no longer
attracted, the  wheel  moves  on  by its  momentum
until  the  next bar  comes into  the  same  position,
causing the  magnet  to be recharged;  this is then
attracted in  its turn, and passes on like the preced-
ing one.
  333.  The spring playing on the break-piece must
be so  disposed that the circuit shall be broken when
each bar reaches the poles, and not be renewed again
until  it has  passed to a greater distance from  them
than that between the next succeeding bar and the
poles, or it  will be attracted  back again, preventing
the continuance of the  motion.
  334.  Vibrating  Armature  Engine. — Fig.  144
represents an instrument in which  the armature, A,
       Fig. 144.       *s  made  to vibrate backwards
                    and forwards  above  the  poles
                    of  an electro-magnet,  M.  The
                    armature, when on one side, is
                    attracted by the poles until  it
                    arrives directly over them.   As
                    it reaches this position, the cir-
                    cuit is  broken by  the break-
                    piece, and the  bar moves on by
                    the momentum it has acquired,
                    for some distance.  The circuit
                    is  then  renewed, and it moves
                    back towards  the  poles.  The
                    arrangement of the  break-piece
                    is  such,  that the current circu-
lates while the  armature is approaching  the poles on
 
      REVOLVING  electro-magnet.   211

either side,  and  is interrupted while it is  receding
from  them.  A continuous vibration  is  thus  occa-
sioned, which imparts motion to  a fly-wheel, and to
a hammer, which strikes the bell  seen in the cut.
  335.  Fig.  145 represents another form of the in-
                              strument, in  which
                              the  axis  of motion
                              of  the  armature  is
                              below   the  magnet.
                              The moving bar ex-
                              erts its  greatest force
                              when   passing   the
                              poles,   and   at   the
                              moment  when   the
                              crank is in the best
 position  for driving the fly-wheel.
  336.  Revolving  Electro-Magnet. — In the in-
 strument  represented in Fig.  146,  a steel  U-magnet
 is fixed  in a vertical  position, and a small straight
 bar of soft iron,  enclosed in a helix, is so arranged
 as to revolve between its poles.    The two extremi-
 ties  of  the insulated wire surrounding this electro-
 magnet, are connected  respectively with the segments
 of a pole-changer ($ 191), on the shaft.  The silver
 springs,  which press upon the pole-changer, are  at-
 tached to two stout brass wires,  passing through the
 brass arch surmounting the U-magnet,  but  insulated
 from  it by the  intervention  of ivory or  horn;  each
 of these  wires supports  a brass cup for connection
 with  the battery.  These springs must be  so placed
 with  regard  to  the segments, that  the poles of the
 
212
DAVIS'S  MANUAL.
revolving bar shall be reversed at the moment when
it is passing the poles of the fixed magnet.
  337.  On making  connection with  the  battery,
when the bar is at right  angles to the plane of the
magnet,  it immediately  acquires a  strong  polarity.
Its north pole is then attracted  by the south pole of
the steel U-magnet and  repelled by the north pole.
The south pole of the bar,  on the contrary, is re-
pelled by the similar pole  of the upright magnet,  and
                            attracted by its opposite
                            pole.  These four forces
                            conspire in bringing the
                            electro-magnet between
                            the poles of the U-mag-
                            net.  When it reaches
                            this position, each seg-
                            ment of the pole-chang-
                            er leaves the spring with
                            which it was in contact,
                            and passes to the other.
                            As the bar  is  moving
                            past  the  poles by  the
                            momentum it has gain-
                            ed, its  magnetism  is
                            destroyed   for   a  mo-
                            ment, and immediately
                            restored in the opposite
                            direction.    Each  pole
                            of the bar is now re-
pelled by that pole of the permanent  magnet which
it has just passed, and attracted by the opposite one ;
 
     Ritchie's  revolving  magnet.  213

it consequently moves on, the polarity being reversed
twice in each revolution.
  338. Instead of  using a pole-changer,  the  poles
of the electro-magnet  are reversed  in  the  following
manner in  the instrument  known as  Ritchie's Re-
volving Magnet.  The ends of the wire surrounding
the revolving  bar dip  into mercury contained in a
circular cistern of ivory, fixed between the poles of
the U-magnet below the bar.   This cistern  is divided
into two  separate cells  by low partitions of ivory, so
arranged  that, when  the electro-magnet  is passing
between  the poles of  the steel magnet, the ends of
the wire  may  be moving  across the partitions and
just above  them.  On  supplying the cells with  a
proper quantity of mercury, its surface will be found
to curve downwards on every side towards  the ivory,
so that its general level  will be higher than the par-
titions ; thus allowing the extremities of the wire to
be immersed in it, except when passing across them.
A wire connected with a brass cup, for making com-
munication with  the battery, projects into  the mer-
cury in  each  compartment of  the basin.  At the
moment when  the  wires quit the  mercury to pass
across the  partitions,  a  spark is seen.  When the
machine is put in motion in a dark room, these sparks
give  rise  to an optical illusion  of the same  character
as that mentioned in the description of the Revolving
Spur-Wheel, causing  the bar  to appear at rest in
the  position it is in when the sparks are  emitted.
  339.  The revolution is more rapid  where the
pole-changer is used,  than  in Ritchie's  instrument, 
214
davis's  manual.
Fig. 147.
and  may be made still more so, by employing  a U-
shaped electro-magnet in place of the stationary steel
magnet.   In this case, the rotation is not reversed by
changing the direction of the current, as it is when a
steel magnet  is used, since the poles of both electro-
magnets are  reversed at the  same  time, and  their
relative polarity  remains  the  same.
   340.   Revolving   Bell  Engine. — This  instru-
ment, represented in Fig. 147, is similar in principle
                      to  the  one  last figured, the
                      U-magnet, however, being in-
                      verted,  so  that  the revolving
                      electro-magnet  is near  the
                      baseboard;   the  pole-changer
                      is on the axis below it. There
                      is, in addition, an arrangement
                      for striking  a bell,  which is
                      fixed above the  magnet.  To
                      the axis of the  revolving bar
                      is  attached an endless screw;
                      this screw acts  on a  toothed
                      wheel, which is  provided with
                      a pin projecting laterally, for
                      the  purpose  of moving the
                      hammer.   As the wheel turns,
                      the pin  presses upon  the han-
                      dle of the  hammer, raising it
from  the bell until  it is  released  by  the pin at a
certain point of the revolution; when a spiral spring,
fixed  to  the handle, impels the hammer against the
bell.
 
    rotation  by  earth's  action.  215

  341. If the wheel  has  100 teeth, as in the cut,
the electro-magnet must revolve 100 times in order
to  produce one  revolution of the wheel, and  con-
sequently  one stroke  upon the bell.  The velocity
of  the rotating  bar  is measured by counting  the
number of strokes in a given time ; it may make 100
or more revolutions in a second.  In order that the
motion of the  wheel may raise  the  hammer,  it is
necessary to transmit the battery current  so that the
bar shall rotate  in the proper direction.
  342.  Registering   Revolving  Magnet. — Fig.
                  148 represents an instrument in
                  which  the number of  revolutions
                  of the  electro-magnet  in a given
                  time is registered by  means  of
                  clock-work  connected with  the
                  shaft.  On the dial-plate are three
                  pointers, which mark the revo-
                  lutions up to 1000.   The  time
                  occupied by any known number
                  of revolutions at once  enables us
                  to ascertain the  speed of  the  ro-
                  tating  bar.  Though  very great,
                  it is  necessarily somewhat  less
                  than  when the  bar   carries  no
                  machinery.
  343. Electro-Magnet revolving by the Earth's
Action.—As the earth itself exhibits magnetic po-
larity,  an electro-magnet  may be made   to  revolve
by  its influence; though,  in  consequence  of the
feebleness  of the action, the  instrument must  be
 
216
DAVIS'S  MANUAL.
Fig. 149.
constructed  with some  delicacy.  A small electro-
magnet, (Fig. 149,) is so supported as to have freedom
of motion in a vertical plane, like the dipping needle,
a pole-changer being secured on its axis of motion.
The  springs  which  press upon  the pole-changer
should be disposed in such a manner that  the polarity
of the bar may be reversed when in the course of its
revolution it reaches the line  of the dip.   In high
                           latitudes, it will be suf-
                           ficient  to  arrange the
                           pole-changer so  as  to
                           reverse the  poles when
                           the bar becomes verti-
                           cal.  The shaft on which
                           the  bar  revolves, rests
                           on friction rollers.
                              344.  On  placing the
                           electro-magnet  horizon-
                           tally in  the  magnetic
                           meridian, that is to say,
with its extremities directed north  and south, and
transmitting the battery current, its north pole  (in
this hemisphere) immediately  inclines  downwards
towards the earth, in the same manner as that of the
dipping  needle.   The  momentum thus  acquired
carries it past the line of the dip into a vertical direc-
tion.  As soon as  it reaches this position, the poles
are  reversed, and  it continues  to  move on  in  the
same direction as long as the  battery connections are
maintained,  revolving with a moderate  velocity.
   345.  In Fig. 150 is represented an electro-magnet,
 
MAGNET  REVOLVING  IN  A  COIL.   217
bo supported as to revolve by the earth's action in
a horizontal plane, instead of a vertical one.   In this
        Fig. 150.         case, the instrument  must be
    MMttMMir&iuiiiiiunmumin  placed in such a position that
    ^11/JJiJlWil/ljlHli^^jiJHJllllJliiHilliiiiP  tne p0iarity shall be  reversed
                        when  the  revolving  mag-
                        net assumes the direction of
                        the compass-needle,  pointing
                        north and south.
                          346.  When a steel  mag-
                        net is placed in a proper  po-
                        sition near the revolving bar,
 ^                 ^ in either of the  instruments
 whose  motion depends on  the earth's  influence,  it
 rotates  with  much greater speed than by the action
 of terrestrial magnetism alone.   Its motion  may be
 reversed,  notwithstanding the opposing influence of
 the earth, by disposing  the permanent  magnet  in a
 suitable manner.
   347.  Electro-Magnet revolving within a Coil.
 — Fig. 151 represents an instrument in   which a
 straight electro-magnet revolves within a circular coil.
 The same current traverses the coil and  the wire sur-
 rounding  the rotating bar,  but  its direction is  changed
 only in the latter.   When the  circuit is completed,
 the revolving bar moves so as to bring its poles into
 a direction  corresponding  with  those of the  coil.
 This  motion depends upon  the same  cause as that
 of a galvanometer needle, (<§> 158.)  As the  poles of
 the coil  are  situated in  the  line  of its axis,  the
 springs pressing on the segments of the  pole-changer
               19
 
218
DAVIS'S  MANUAL.
 are so arranged  as  to reverse the current when the
 electro-magnet is at right angles with the coil.  The
   Pis: 151     north pole  of  the magnet places itself
               within the  north pole of the coil, and
               not,  as might at  first  sight  be ex-
               pected,  within its  south pole.   This
               apparent anomaly is due to the circum-
               stance of the  magnet not being pre-
               sented to  the coil from the  outside,
               but lying within, with its centre coin-
               ciding with that  of  the coil.  If  a
               magnetic needle is  brought up to  a
               helix, its  north pole is attracted to-
               wards the south pole of the helix, (see
 § 268), and  passes  within  it, until its centre  lies in
 the centre of the coil.  In  this position, its poles lie
 in the same direction as those of the electro-magnet
 described above.
   348.  Double  Revolving  Magnet. — In this in-
 strument,  represented  in  Fig. 152,  there  are two
           py   ,52            electro-magnets  of the
                             U form and of the same
                             size,  arranged  to  re-
                             volve on vertical axes.
                             At s, on  the  shaft of
                             the  lower magnet, is a
                             silver ferrule, on which
                             presses a wire connect-
                             ed with   one  of  the
                             screw-cups.    On   the
shaft,  of the upper  magnet  is a break-piece.   When
 
REVOLVING  WHEELS.         219
the current  passes, both  magnets  become  charged,
and, their opposite poles attracting each other, they
move in opposite directions  until they come into the
same line.   At this moment the circuit is interrupted
by  the  break-piece, and  the  poles move  past each
other by their  acquired momentum.   The  circuit is
then renewed,  and the magnets  continue to revolve
in opposite directions.   Since the shaft of the lower
magnet sustains the weight of both,  the lower  one
moves with less speed  than the other, in  consequence
of the increased friction.   Reversal of the  poles by
a  pole-changer is  not  resorted to, on  account of the
feeble  repulsion between  electro-magnets.
   349.  Revolving Wheels,  with   Electro-Mag-
net.— In  the  instrument  represented in  Fig.  153,
                          motion is obtained on the
                          same  principle  as in the
                          Revolving    Spur-Wheel
                          ($180), an electro-magnet
                          taking the place of the steel
                          magnet.   There are  two
                          wheels ; of these, the up-
                          per and larger one is partly
                          supported  by springs, its
                          circumference resting on
                          that of the smaller wheel.
 The current  traverses in  succession  the coil of the
 electro-magnet and the wheels.   It  passes from the
 axis of the smaller wheel to  that part of  its circum-
 ference which touches the circumference of the other,
 and thence to the axis of the  larger one.   The lower
fV. 153
 
220
DAVIS'S  MANUAL.
wheel  is not merely carried round by the other, but
those parts of both which are  conveying the current
tend to move away from between  the  poles  in the
same direction, causing the two  wheels  to revolve in
opposite  directions.
  350.  Revolving  Wheels.—A  better  form  is
shown  in Fig.  154, in which the wheels move be-
Fig. 154.
                             tween  the  poles of a
                             steel U-magnet, whose
                             legs are brought very
                             near together. In these
                             instruments  no  mer-
                             cury is used.   Fig. 154
                             is similar  to  the  Re-
                             volving  Disc (<§> 184),
                             and would  have been
                             described  in  connec-
                             tion with that, had not
                             that part of the volume
gone to press before this instrument was contrived.
  351.  Electro-Magnet,  revolving  on its Axis.
— The instrument represented in Fig.  155, is similar
to the one described  in  $ 167,  except that the  re-
volving bar is of iron, enclosed  in  a helix  which
rotates  with  it.   The battery current traverses the
helix  and one half of the bar.  As the bar  becomes
an  electro-magnet,  it revolves  like the one  repre-
sented in  Fig. 57, except  that  the direction  of the
rotation is not changed  by  reversing the  current,
since the poles are at the  same time reversed.  From
the power of  the magnet,  the motion  is very rapid. 
MECHANICAL  POWER.         221
The revolution of either an electro-magnet or a steel
magnet  on its axis is properly classed with that of a
           jpj  l55            conductor around  a
                              magnet.  When  the
                              conductor and mag-
                              net  are  fastened to-
                              gether, the latter is
                              carried round by the
                              movement   of  the
                              former, as  stated in
                              $ 171.  Instead   of
                              fastening a conduct-
                              ing   wire   to  the
                              magnet,  the current
                              may be  transmitted
                              through the magnet
                              itself,  with the same
                              result.
  352.  Electro-Magnetism as  a  Motive  Power.
— The  great velocity  of motion,  and the  strong
attractive force exhibited by many of the small elec-
tro-magnetic   instruments, naturally  suggested  the
application of this power  to the purposes of the arts
as a mechanical  agent; and numerous  experiments
have been made with this  view, but hitherto without
success.  Professor Henry was the contriver  of the
first instrument whose motion  depended upon mag-
netic attraction and repulsion.   In his little machine,
an  electro-magnet, whose polarity was  alternately
reversed was  made to vibrate above the north poles
of two  straight steel  magnets.   He, however, made
              19*
 
222
DAVIS'S  MANUAL.
no attempt to apply this power to practical purposes
There are obstacles of a purely mechanical character
in the way of its  employment; these,  though  im-
portant, are not  perhaps  insurmountable.  But  the
most  serious difficulties are those which arise from
the nature  of the power.   The  motion of the at-
tracting poles of two electro-magnets towards each
other, actually lessens  the attractive force  in pro-
portion  to the velocity with  which  they approach;
the same  thing occurs  in  the recession of mutually
repelling  poles.   These  phenomena  are  due  to  the
influence  of secondary electric currents produced by
the motion, which flow against the  battery current,
and  of course  partially neutralize  its  magnetizing
power.   The  secondary currents present a  very  for-
midable obstacle, as their opposing influence increases
with  the  size of the machine in a  rapid ratio.  An
appreciable time is also required for  the communica-
tion  and  removal  of  the  polarity of large electro-
magnets,  and the purest  iron retains a considerable
degree of magnetic power after being highly charged.
To the  action  of these  and some  other causes  is
owing the fact, which was early discovered by those
engaged  in  these investigations, that  the  smallest
machines  possess  by far the  greatest  proportional
power.   Some of  these difficulties  are obviated by
the axial  motion,  recently proposed as a source of
mechanical power, by Dr.  Page, one of the earliest
and  most persevering, as well as ingenious experi-
 menters  in  this  department.  In  his  instruments,
modified forms of some of which have been described 
INDUCTION  BY  THE  EARTH.    223
on previous pages, the force by which an iron bar is
drawn into a helix is the source of the  power.  A
stroke of some length may  thus  be obtained,  and
there  are no attracting or repelling  poles to produce
interfering  secondary  currents.
        III.  BY THE INFLUENCE  OF THE EARTH.

       353.  An unmagnetic  bar of iron,  placed  in  the
    direction assumed by the dipping needle (see $210),
    acquires temporary magnetism by induction from the
    earth.   That  extremity  which  is  directed towards
    the south magnetic  pole  ($218), receives north  po-
    larity, and  the other end south polarity.   A  bar of
    soft iron  held in  a horizontal  position, especially
    if directed  east  and west,  attracts  indiscriminately
    either pole of a magnetic needle, as the earth exerts
    no appreciable inductive action upon it.
       354.  In Fig. 156, A B  represents a bar of iron,  pre-
    sented  in a horizontal position to the north  pole of
    a magnetic needle,  N S.   The pole is now attracted
    by the  bar.   Keeping  the end B in the  same place,
    raise  the end A so as to bring the bar into  the position
    C D.   As  the bar  is raised, the north  pole  recedes
    from C, as  indicated by  the  dotted  lines in the  cut.
    The  strongest action is  exerted when the bar is  in
!    the line of the dip, or in this latitude nearly vertically
    over  the  needle.   By  carrying the  bar below the
    needle, still preserving the  same direction, its upper
1    end will  be found  to attract N and repel S.   These 
224
DAVI S ' S  MANUAL.
phenomena  are sufficient to show that C  D has be-
come a magnet, with C  for its  north pole.   On  re-
Fis-. 156.
versing the bar, so as to bring the end D downwards,
C  immediately  becomes the  south pole: thus the
polarity  may be changed at  pleasure,  the  induced
magnetism being only  temporary.   If the  bar  is
brought very near to the pole of the needle, the in-
ductive  action of the earth will  be overpowered by
that of the needle, causing attraction to be exhibited
iii  every position.
  '^55.  Except  in  the  vicinity of the equator, it  is
sufficient to hold the  bar vertically, as the line of dip
approaches the perpendicular in  high  latitudes.  In
resequence of this inductive action of  the earth, all
large bars of  iron standing in an upright position, aie
more or less magnetic, their lower ends,  in this hemi-
sphere,  being north  poles.   When they  have re-
mained for a long time  in this situation, the polarity
does not disappear on changing their  position. 
INDUCTION  BY  THE  EARTH.     225
Fig. 157,
  356.  The induction of magnetism by the earth is
greatly facilitated by causing a movement among the
particles  of  the  bar,  as  by  percussion or  twisting,
Let a bar of iron be held in the line of the dip, and
                           its  lower end brought
                           near the north pole of a
                           magnetic needle.   The
                           pole will  be  repelled,
                           and will come to rest at
                           some distance from  the
                           bar,  as shown in  Fig.
                            157.   Now  strike  the
                           upper  end  of the  bar
                           with a hammer, and the
                           induced magnetism will
                           be  so  much  increased
                           that  the  needle  will
                           swing  round,  and  its
                           south pole be drawn to
                           the bar, as indicated by
                           the dotted lines  in  the
                           cut.   The polarity thus
                           induced is not reversed
                           by merely inverting the
                           rod, but the  aid of per-
cussion will be required,  in order to remove or reverse
the magnetism.   This is especially  the case when a
steel bar  is employed instead of an iron one.
   357.  Take a piece of iron wire, and, placing it in
a vertical position, twist it  powerfully.  It will now
be found to sustain iron  filings at its extremities, and
/.--'
 
226
DAVIS'S  MANUAL.
to turn itself north and south, when balanced on a
pivot, as shown in Fig.  158.   The end which was
                          downwards  becomes  the
                          north pole.
                            358.  The magnetism,
                          in these cases, is  not due
                          directly to the percussion
                          or   twisting,  either  of
                          which merely favors  the
action  of the  earth.  A  considerable degree of per-
manent magnetism may  be communicated to a steel
bar,  by placing it vertically on a large  mass of iron,
and striking its upper end repeatedly with a hammer;
it acquires much greater power if struck while rest-
ing on iron than  on any  other  substance.
   359.  Percussion may be used to  facilitate the re-
moval  of magnetism.  Thus the polarity of a steel bar
magnet may be lessened, or even entirely  destroyed,
by repeated blows of a hammer, while  held horizon-
tally east and west.  This process is very convenient
for removing  slight degrees of magnetism from iron
or steel bars.   In discharging  steel magnets by  the
methods previously  described,  it is sometimes  dif-
ficult  to  effect a complete removal of their mag-
netism.  In such cases,  the desired result  may be
attained,  after having nearly  discharged  them, by
following  the  process  now given.  Merely falling
upon the floor often injures the power of a magnet
considerably,  in  consequence  of the  vibration  ex-
cited among the particles of the steel.
 
MAGNETISM.
                       in.

      INDUCTION  OF   ELECTRICITY.

   I.  BY THE INFLUENCE  OF A  CURRENT OF
                  ELECTRICITY.

  360. That  branch of the  science of electricity
which treats of the phenomena presented by it when
at  rest, is termed  Electro-statics: the branch which
relates to  electricity in motion,  is  called  Electro-
dynamics.  The phenomena which characterize the
latter  state  are classified  by  Professor Faraday  as
follows :  " The effects  of  electricity in  motion,  or
electrical currents, may be  considered as, 1st,  Evo-
lution of heat; 2d, Magnetism;  3d, Chemical  de-
composition;  4th,  Physiological phenomena;  5th.
Spark."  Many of the phenomena presented by  elec-
tricity in motion  are closely related to magnetism,
and it is usual to treat of  them in connection  with
that subject, as in the  present volume, rather  than
with  electricity.
   361.  Before entering upon  the particular subject
of the present chapter,  that is, the inductive action 
228
DAVIS'S  MANUAL.
of currents, it will  be advisable to  occupy  a  few
pages with a comparison of some of the phenomena
exhibited by  electricity in the  two  states of  mo-
tion  and rest,  as  induction is exerted in both.   The
nature of the  action is entirely different in  the  two
cases.
  302.  An  electrified body attracts light  substances
in its neighborhood,  having  previously induced in
their nearest ends the opposite electricity to its own ;
and on their approach communicates to them  a  part
of its charge,  when, if insulated, they are instantly
repelled  by it.  A.  wire conveying a current  exerts
no such influence upon light  bodies, although  placed
in the immediate vicinity.
  363.  In the case of electricity at rest, two bodies,
charged  either  positively  or negatively,  repel each
other; while if one  is charged with positive and the
other with negative electricity, they exert a mutual
attraction.   Electrical currents, on  the  contrary, at-
tract  each other  when flowing parallel in the same
direction, and repel each  other when  flowing in
opposite directions.   The result is the same whether
two different currents or two  portions of one current
are experimented on.
  364.  Attracting  \nd Repelling Wires. — The
instrument represented in  Fig.  159  is designed to
exhibit the attractions and   repulsions  of currents.
Two  wooden  troughs for  containing mercury  are
supported opposite to one another, each being divided
into  two  oblong  cells by a partition in the middle.
Each of the four portions of mercury  thus insulated, 
ATTRACTING  AND  RETELLING  WIRES.  229
is connected  by means of a wire projecting  into the
cell, with one  of the screw-cups fixed  at the  ends
Fig. 159.
                             of the troughs.  The
                             points of   two  rec-
                             tangular  wires, A and
                             B, rest in the opposite
                             compartments of the
                             troughs.   This  mode
                             of support allows the
                             wires  to be  placed
                             nearer to  or farther
                             from  each  other,  at
                           D pleasure, still  remain-
                             ing  parallel.   These
                             wires are balanced by
                             two brass  balls, b  b,
                             attached to  them be-
                             low,  which are capa-
ble of being raised or depressed by means of a screw
cut on  the  wire ;  they may thus be  so  adjusted that
the wires will be moved from their vertical  position
by a very  slight  force, their upper  portions rocking
towards or away  from each other, without  requiring
any motion of the points of support.
  365.  Cups  C  and E, being  united  by  a copper
wire, connect  cups D and  F with the  galvanic bat-
tery.   The current  will now traverse A  and B  in
succession  flowing  in  the  same  direction in both,
and they will  be  seen  to incline towards each other.
The motion is slight, but may be  made considerable
by breaking and  renewing  the circuit in correspond-
              20
 
230
DA VIS'S  MANUAL.
ence  with their  oscillations.  The  same  effect is
produced  by uniting D with F,  and connecting C
and  E with  the  battery.   If a powerful  current is
employed, the wires still attract each  other  when
separated  to a considerable distance, by moving the
points which rest in the mercury  to the farther ends
of the cells;  with a feeble battery, the wires should
be placed near to one  another.
  366.  Let the cup C now be united with D, and E
and  F be connected with the  battery.   This will
cause the  current to flow  in opposite directions in
the two wires, and they will recede from each other;
the extent of the motion may be increased, as before,
by alternately opening and closing the circuit.  Cups
C and D may be connected with the battery with the
same result, E and F being united by a wire.
  367.  The current, instead of traversing the wires
in succession, may be divided  into  two portions by
uniting C with D, and  E with F, by two  wires, and
then  connecting the  battery either with C and F or
D and E.  In this case, the two portions of the cur-
rent flow in the same direction in A and  B, causing
them to  attract each  other.  By uniting  C with E,
and  D with  F,  the currents  in  A and  B flow in
contrary  directions, and the wires exhibit a mutual
repulsion.  The  movements produced by a divided
current are feebler than when it  traverses the  wires
in  succession, unless  the battery employed  is so
powerful that one of the wires singly is not able to
convey the whole of the electricity supplied by it.
   368. These attractions and  repulsions are some- 
ATTRACTING  CURRENTS.       231
times called magnetic, the two currents, when flowing
side  by side, acting  upon each other like  two mag-
nets  presented  end  to  end.   In fact,  if  two short
pieces of iron wire be suspended end to end, and at
right angles to the conducting wires, the magnetism
induced  in them by the currents  (see $ 254) will
cause them to exhibit similar attractions and repul-
sions to those of the wires themselves.   It is, how-
ever, preferable  to  regard this peculiar action  as a
primary one; it being  highly probable that the po-
larity of even a  steel magnet is due to electric cur-
rents circulating within its substance.  The mutual
actions of two magnets, or of a magnet and a current,
would  thus be secondary effects, depending upon the
attractions and repulsions just described.
  369.  It  is not essential  that the  current  should
traverse  metallic wires  in  order  to  produce these
effects.   Two streams of machine electricity flowing
through a  vacuum, or even through the air, exhibit
the phenomena  very satisfactorily.   The attraction
of currents moving  in  the  same  direction  may  be
shown by  the following arrangement:  Connect the
inner coatings of two Leyden  jars with  either the
positive or negative  conductor of a common electric
machine,  their outer coatings being  insulated suf-
ficiently from each  other to prevent the passage of a
spark between them when the jars are discharged in
the mode  about to  be described.  With the exterior
coating of each jar  is connected a wire having one
end  free.   These ends are  left free for the purpose
of being placed on  a card over which  the charge is 
232
DAVIS'S  MANUAL.
to be passed.   The common  enamelled cards should
be  used, as they  receive a dark-colored and  perma-
nent  mark from  the passage  of the spark over their
surface.  A third wire,  attached  to  the discharging
rod, is also to rest  on  the card,  at such a distance
from  the other  two wires that the sparks from  the
jars may be able to pass.   The ends  of the wires
proceeding from the outsides of the  jars should be
placed a quarter or a half of an inch apart, and nearer
to one another than to the third wire, which is to be
equally distant from both, so that two straight lines
drawn from them to the third wire, would  form the
letter  V.   The  jars being  charged  (during  which
process the exterior coatings should,  of course, be
uninsulated),  arrange the  points as  directed, and
bring up the ball  of the  discharging rod to the con-
ductor.  The inner coatings  being  connected, and
the outer  ones  insulated, the current is obliged to
divide into two portions as it  proceeds from the point
attached to the discharger to those in connection with
the outsides  of  the jars.   The two sparks will thus
pass simultaneously over  the surface of the card, and,
were  they not affected  by each  other, would leave
a mark in the shape of the letter V.  It will be found,
on  the contrary, that the track left on the card will
be more or less in the  form  of the letter Y, the two
currents coalescing  in their passage over  its surface.
The result will be the same,  whether the jars  are
charged positively or negatively  on the  inside.  If
the wire  connected with the discharger  is  placed
under  the  card while  the others  are  on the  upper 
            CONTRACTING   HELIX.        233

side, the card will be perforated in one or more places
by the  passage  of the  electricity.
  370.  The experiment may be  varied, by con-
necting with the discharging rod a wire whose ends
may both  rest on the card at the same distance from
each other as that between the two wires attached to
the exterior coatings of the jars.   The two  sets of
points being arranged parallel to each other, and their
distances  properly  adjusted,  the two  currents  will
remain  separate during  the whole of their passage
over the  card;  and it  will  be seen  by  the  marks
which  they  leave,  that,  instead  of proceeding in
straight and parallel lines, they form curves  whose
convexity is turned towards each other.  The  cur-
vature  of  the  lines is  greater  in proportion to their
proximity;  but  if the  points  are placed too near
together, both currents  flow  in one track, not sepa-
rating  until  they  reach  one of the  wires  connected
with the outside of the jars.   The resistance  of the
air and other causes often occasion a stream of elec-
tricity  to  follow a very crooked path in passing over
a card.  Hence  the lines traced by the two currents
in these experiments may be  irregular, though the
tendency  to converge is  perfectly  evident.
  371.  Contracting  Helix. — The  mutual  attrac-
tion  between different portions of the same current
moving in the same manner,  may be  rendered  evi-
dent by the instrument represented  in Fig. 160.  A
wire,  coiled  into  a loose helix,  is  supported in a
vertical position  by a  brass  pillar  connected with
one of the screw-cups on the base board.  The lower
              20* 
234           DAVIS'S   MANUAL.
end of the helix dips into mercury contained in a
glass cud with a metal bottom, by  means  of which
                             the mercury is brought
          ^8- 160,            into  connection  with
                             the  other screw-cup.
                             When the  battery  is
                             applied, the portions of
                             the current traversing
                             the different turns of
                             the helix of course flow
                             parallel to each other,
                             and in the same direc-
                             tion.   Their  mutual
 aiiiiiiiiiiin......mi.......mfmmmsmmK^mA attractions  cause the
 ®                          turns of  the  helix  to
 approach each other, shortening  it sufficiently to lift
 the end  of  the wire  out of the  mercury.   This
 interrupts the current, and  the  helix  is lengthened
 again by the elasticity of the  wire composing  it,
 producing continued vibration.   A  spark is seen  in
 the glass cup  at  each  rupture  of contact.   It  is
 necessary to  adjust the quantity of mercury so that
 the  wire may  be  raised out of  it  when the coil
 shortens itself.
   372.   A bar magnet passed partly within the  helix,
 as  in  Fig.  161, causes  a  more  active movement.
 One pole of a U-magnct, or an iron bar, produces the
 same effect.   If a bar magnet or an iron  rod, of the
 same length  as  ihe  helix, is passed wholly within,
 the turns of the helix contract,  above and  below
 the centre,  while near the centre there is no move-
 
ELECTRO—DYNAMIC  REVOLVING  COIL. 235
ment, the influence of the magnet maintaining it in
a state of rest.   When an  iron bar is introduced, it
             Fig. 161.          is magnetized by the
                              current  in  the helix,
                              and exerts the  same
                              influence as the steel
                              magnet.  The action
                              on each turn of the
                              helix  is the  same as
                              with  De  la  Rive's
                              Ring, ($186.)  The
                              direction of  the cur-
                              rent   determines  in
                              which   direction the
                              steel magnet must be
                              introduced,  in  order
                              that  the  helix may
                              contract and break the
                              circuit.
   373.  Electro-Dynamic  Revolving  Coil.—The
 mutually attractive  and repulsive action of  currents
 may be made to produce  rotations analogous to some
 of those strictly called  electro-magnetic;  as in  the
 instrument  represented in  Fig.  162,  which consists
 of a circular coil of insulated wire, B,  fitted to rotate
 on a vertical axis  within a larger  one, A,  mounted
 on a brass pillar.  The inner coil has  a pole-changer
 fixed to its axis of motion for the purpose of reversing
 the current  twice in  each  revolution.  The current
 may  traverse  the  two coils  in  succession,  or be
 divided  between them,  but  its direction  must be
 -Wicrp.d only in the  interior  one.
 
236
Davis's  manual .
   374.  The inner coil being  placed  at right angles
to the other,  and the cups  on the stand connected
                   with  the  galvanic  battery,  the
                   faces  of each coil  immediately
                   exhibit north  and south polarity,
                   like  those  of  De  la Rive's Ring
                   (§  185);  and  B is  obliged  to
                   make a quarter of a revolution in
                   order  to   bring   its  north  pole
                   within the north pole of A. so as
                   to make their  directions corre-
                   spond. As soon as it reaches this
                   position, the  current is reversed
                   by  means of the pole-changer,
and its south  pole now being  within  the  north  pole
of A,  it  continues to move on  in  the  same direction.
The  motion,  in  this case, depends  upon  the same
principle as  those of the wires  in  the instrument
represented  in Fig.  159; but  it is  more convenient
to refer them to  the  polarity exhibited  by a current
flowing in a  circle, as was  done in  describing the
Revolving  Coil,  (Fig. 69.)
   375.  It is, however, easy to explain the revolution
with direct reference to the mutual action of the cur-
rents.  As  these  circulate in the same direction  in
every convolution of each coil, they may be regarded
as two single circular currents.   Now, suppose the
current  in  A  to  be ascending by its left side  and
descending by its right side.    If B is placed at right
angles to A, with the current descending in  the  side
towards the spectator, this side will  be  attracted by
 
ROTATION  OF  MERCURY.       237
Fig. 163.
the right  side of A, and repelled by the left.   The
farther side of B, on the contrary, will be repelled by
the right  side  of A, and attracted  by its left  side.
These  forces conspire in bringing the two coils into
the same direction ; when, the current being reversed
by  the  pole-changer, each side of B is repelled by
that side  of A which is nearest, and the motion is
continued in the same direction.
  376.  Electro-Dynamic  Revolving  Rectangle.
— Rectangular coils  may  be used  in  place of cir-
                cular  ones, with the same result, as
                in the instrument represented in Fig.
                163, which  is analogous to  the one
                described in § 193.   The inner rect-
                angle revolves in the same  manner
                as the coil  B in the instrument last
                described, and the  rotation  is more
                rapid  than  with the circular  coil.
                In consequence of the width of the
                rectangular coils being less than their
                height, the sides of the interior one
                are near those of the other during
                the  whole  revolution.   This  cir-
cumstance is the occasion of its  greater speed.
  377.  Instrument for  showing  the  Revolution
ok  Mercury.—The  instrument  represented  in Fig.
161, is designed to  exhibit the  revolution of mercury
within a helix.   The mercury is  contained in a brass
cup, within which  is fixed a small  watch  crystal.
The brass is  covered by  this, except at the  upper
edge, where a ring is exposed, which is amalgamated.
 
238
DAVIS'S  MANUAL.
This  ring  is  in metallic  connection  with  one of
the screw-cups on the  base board.  Surrounding the
         Fig. 164.          mercury cup  is a helix,
                          one of whose ends  con-
                          nects  with  the remaining
                          screw-cup.   Its other end
                          is  left free, so as to be
                          inserted into the  shallow
                          cup.  An iron cup,  with
its rim  amalgamated,  and a  watch crystal  secured
within it, may be substituted for the brass cup.   The
movement  of the mercury is then more rapid,  as
the influence of the  iron, which  becomes an electro-
magnet,  aids that of the helix.
   378.  Sufficient mercury being introduced, and the
battery  connections  made, insert the free end of the
wire into the mercury.  The current now flows in a
circular direction in  the helix, but  in the mercury  it
passes from the end of the wire to each portion of
the circumference of  the  cup in the  direction of a
radius.   The reaction  between the radiating and the
circular  currents, causes the mercury  conveying the
former to revolve around the point of  the wire, that
being  the  centre from  which the  currents radiate.
This rotation  is rapid,  and  produces  sufficient cen-
trifugal  force  to  make the  mercury  hollow in the
centre.   As the end of the  wire is thus uncovered,
the current is  interrupted  and the revolution ceases.
 When the mercury  returns to its level, the current is
renewed,  to  be  again  suspended  as  before.  The
rotation  is rendered more visible by  putting a drop
or two  of muriatic  acid on  the mercury.
 
        ELECTRO — DYNAMIC  THEORY     239

  379.  The circular  currents in the helix may be
regarded as made  up  of  short  rectilinear  currents,
each of which flows at right angles to the radius of
the helix.  Confining  our attention to the action of a
single one of these currents, it will  be seen that two
only of those  passing  through the  mercury are par-
allel with it.  Of these, one is moving in the same
direction, and  is attracted;  the other, on the opposite
side of  the inserted wire, moves  in the reverse direc-
tion, and is repelled.   These two forces conspire  in
giving a motion  of rotation to those portions of the
mercury which are  acting  as conductors.   The two
radiating currents which are precisely at right angles
to the  rectilinear one, and also  all the oblique cur-
rents,  are  attracted and  repelled by  the  rectilinear
current, in  such  a manner that  they  tend to place
themselves  parallel with  it.  As the  influence of
every portion of  the current in the helix  urges each
of  the  radiating  currents to move in one and  the
same direction,  a  rapid  revolution of  the mercury
conveying them  is  the consequence.  The rotation
of  the mercury mentioned  in $ 285, is produced in a
similar manner with that obtained in this instrument.
   380.  In connection with the subject  of  the at-
tractions and repulsions of currents, it will be proper
to give a slight sketch of the Electro-Dynamic Theo-
ry of Ampere.   This  theory ascribes  the  actions of
currents upon each  other, of  magnets  upon each
other, and those  exerted between currents and mag-
nets, to one and the  same cause, the mutual  attrac-
tions and repulsions of electric  currents.   In a steel 
240
DAVIS'S  MANUAL.
magnet, the currents are  regarded  as circulating in a
uniform direction, at right angles  to the  axis of the
magnet,  around  the elementary magnetic  particles
(§ 249), forming  closed  circuits.   The resultant ac-
tion of such a system of  currents would be  the same
as that of a  series  of  currents flowing  round  the
circumference of the magnet at each  portion  of its
length and at  right angles to the axis.  This assimi-
lates  the  action  of a steel magnet to that of the
electro-magnet,  with the current  circulating  in  its
helix, and to the action  of  the helix itself.  How
such elementary  currents are excited and  maintained
within the substance of a  good conductor of  elec-
tricity, like steel,  has  not  been ascertained.   It is
supposed  that the currents are  flowing at  all  times
around the  particles of  every  body   susceptible  of
magnetism, but that they neutralize the influence of
each  other, being turned indiscriminately  in  every
direction.   By the process of charging, the currents
are brought into a uniform direction,  and  magnetic
power is  developed.
   381.  Ampere regards  the magnetism of  the earth
itself as due to electric  currents circulating within
it, from east to west, in  planes  parallel, or nearly  so,
to the magnetic  equator.   These currents  are prob-
ably in great  part thermo-electric,  due to the action
of solar heat  on  successive portions of the surface ;
but there are also many circumstances favorable to
the formation of galvanic  circuits in  the interior.
   382.  The  theory of  Ampere  affords  a simple
explanation of the  tangential   action  of a current, 
INDUCTION  OF  CURRENT.      241
 removing the apparent anomaly with regard to the
 direction  in  which  the force  is  exerted.  When a
 conducting wire  is brought  near  a magnetic needle
 and  parallel  to it, the current in the wire is flowing
 at a right angle  to  those in the  magnet.   In  this
 position,  their mutual  action  is  the same  as  that
 described in $ 379.   The currents in the needle tend
 to arrange themselves  parallel  to  that  in  the wire:
 and  to effect this, the needle, if free  to  move, turns
* itself at  right angles to the wire.   The continued
 revolution of a  conducting  wire around a magnet,
 and  of the  magnet  around  the  wire, depends upon
 the  same principle  as  the  rotation of  one  current
 under the influence  of  another.   By substituting a
 helix in place of the magnet, the  revolutions would
 occur in  the same manner, on transmitting the  current.
    383.  When two  helices,  in which  currents  are
 flowing  in the same direction, are  placed end to  end.
 they attract  each other like the  individual turns of
 the coil  represented  in  Fig.  160.  If one of  them is
 turned round so  as  to present its  other extremity to
 the  first, repulsion  is exhibited, in consequence of
 the opposite directions of the currents.   In two  steel
 magnets, presented  end  to end, the currents, accord-
 ing  to Ampere's  theory, act in the same manner as
 those in the helices, and the  poles attract or repel
 one  another on  the same principle.
    384.  We now proceed to consider the inductive
 action of currents,  taking  first in order those  phe-
 nomena  which  are  referable  to the induction  of a
 current  on  itself.   When the  poles  of a small gal-
                21 
242
DAVIS'S  MANUAL.
vanic battery, consisting  of a single pair of plates,
such as Smee's,  or  the sulphate of copper battery,
are connected by a  copper wire of a few inches in
length, no spark is perceived  when the connection is
either formed or broken, or at most a very faint spark
at the moment of opening the circuit; but if a wire
forty or fifty feet  long is  employed, though no spark
is seen  when  contact is made, a bright  one appears
whenever  the  connection  is  broken by lifting one
end  of  the  wire  out of  the  cup  in which it  rests.
By coiling the wire into  a helix, the spark becomes
more vivid.
   385.  The most advantageous length for producing
the spark depends upon the diameter of the wire, and
also upon the quantity and intensity of  the battery.
With a wire one sixteenth of an inch  in diameter,
and  a single pair of Smee's, or the small sulphate of
copper battery, a length of 50 or 100 feet will  prob-
ably give  the  best  result.    An  increased effect  is
obtained by employing  a longer wire, of greater
diameter.  If a battery of higher intensity is  used,
such as  a  single  pair of  Grove's, the length of the
wire may be still further increased.   The greater is
the  quantity  of  the battery, the larger or shorter
must be the wire,  in  order  to transmit the whole
current,  and obtain the  brightest spark.  This pe-
culiar action of a long conductor, either  extended or
coiled  into a helix, in increasing  the intensity of the
current from a  single galvanic pair, at  the moment
when it ceases  to flow, was  discovered  by Professor
Henry, in 1831. 
RIBBON   SPIRAL.
243
  386.  With a wire two or three hundred feet long,
a slight shock may be felt  at the moment of opening
the circuit,  if its  ends, near their connections with
the polos, are  grasped with moistened hands; with a
shorter  wire, shocks  may be  obtained  through the
tongue ;  their intensity increases until  a length of
five or six hundred feet is attained.   A single pair of
plates gives no shock directly ; the peculiar  and con-
tinuous sensation excited  in  the  tongue when the
current from a single pair  is made to pass through it
not being  called a shock.   With a  battery of small
size,  or consisting  of a  number of  pairs, greater
lengths may be used  with advantage for the shock,
as well as for the spark.   The maximum effects of a
small battery are,  as  might be  expected, much in-
ferior to those of a large one.   If the  requisite lengths
of wire  are exceeded, the effects are  lessened.
   387. The  brilliancy  of the spark is  greatly in-
creased by employing a ribbon of sheet copper coiled
into a flat  spiral, instead  of a wire.  A description
and figure  of this  instrument have been  given  in
§ 112.   The  spiral being connected with  the bat-
 tery, a brilliant spark will be  seen,  accompanied by
a pretty loud snap, whenever  contact is broken; and
 if two metallic handles are  attached by wires to the
 cups of the coil, and held in the hands, a slight shock
 will  be felt.   If  the battery  is  in feeble action, the
 shocks may be perceptible only when passed through
 the  tongue.  No shock  can  be obtained  by inter-
 posing the  body in the direct  circuit with the coil, so
 that  the battery  current  may traverse  them  in sue- 
244
DAVIS'S  MANUAL.
cession ;  as  the  electricity supplied  by a single  pair
of plates is of too low intensity to be  transmitted, to
any considerable extent,  by so  poor a conductor as
the human  body.   Professor Henry was the  first to
employ coils of  metallic ribbon for  obtaining sparks
and shocks  from a single pair  of plates.
  388.  Clock-work  Electrotome. — For the pur-
pose of interrupting the circuit rapidly,  in either a
long wire or a  spiral, the  instrument  represented in
Fig. 165 is very convenient.  In the cut, it is shown
                      Fig. 165.
in connection with a ribbon spiral and a single pair
of Grove's battery.   It consists essentially of a bent
copper wire, which, by  means of clock-work set in
motion by a spring, is made to vibrate rapidly, dip-
ping its ends alternately into two glass cups, intended
to contain mercury.   The  spring  is  wound up  by
turning a milled head.  The glass cups are open at
the bottom, to allow the mercury to come in contact
with the  brass pillars into which they are cemented.
These pillars are both  connected  with  one of the
screw-cups on the base  board;  the other  screw-cup 
       CLOCK-WORK  ELECTROTOME.   245

communicates with a brass  cup for holding mercury
on the top of a third pillar.  Into this dips a verti-
cal  wire  attached  to  the  vibrating wire.  Sufficient
mercury  must be put into the  brass cup to keep the
end of the vertical wire covered, and enough into the
glass cups to allow one end of the vibrating wire to
leave the mercury in  its cup a little before the other
end dips into its portion.
  389.  The  clock-work electrotome  may  be  ad-
vantageously used  in connection  with many of the
instruments for  affording sparks and shocks, which
will be  described  subsequently.   The  current must
be  transmitted through the  two instruments  in suc-
cession, by connecting one of the screw-cups  with
one pole  of the battery,  and  the other screw-cup with
one of those attached to the spiral or other piece of
apparatus,  the remaining cup  of  which  is  to com-
municate with the other pole of  the battery.  It  is
better to break the circuit mechanically in this way,
when it is  desirable to obtain the best possible srarks
and shocks, rather than by means  of any interrupting
apparatus worked  by the  battery itself,  as a consider-
able part of the power of the current is then expended
in giving motion to the interruptor.
  390.  On making  connection  with  a  flat spiral,
in the manner shown  in Fig. 165, and turning the
milled head to put the vibrating  wire  in motion, a
brilliant spark will  be seen at each rupture of contact,
accompanied by a loud snap, and causing combustion
of the mercury at  the  point where the spark occurs.
With a battery consisting of a few pairs of plates of
            21* 
246
DAVIS'S  MANUAL.
large  size, the  size of the spark will  be greatly  in-
creased, and the snap become as loud as the report of
a Leyden jar.  The shock will also be pretty strong,
and may  be  increased by covering the mercury in
the glass  cups with a  stratum of oil.  A shock may
be obtained,  especially when  oil is used, on closing
the circuit as well as  on  opening it, though inferior
to that given in the  latter case;  a  faint  spark is also
sometimes seen when the  wire dips into the mercury.
   391.  The requisite  length  and  thickness of the
copper ribbon to give a maximum result depend  upon
the size  of the  battery employed.   With spirals  of
considerable  length,  even if the  copper  be pretty
thick,  two or  three pairs of plates are better  than
one, as the metal opposes some  resistance to the pas-
sage of a current of low  intensity.  A ribbon spiral
of moderate  length interposed in  the  circuit  of a
compound battery, consisting of a considerable num-
ber of small pairs,  produces scarcely any  peculiar
effect; while a coil containing three or four thousand
feet of fine insulated wire will give an intense shock,
though  not a very  brilliant spark, under the  same
circumstances.   The higher the intensity of  the elec-
tricity  and the smaller its quantity, the less is the
size  requisite in  the  metallic  conductor,  and the
greater may  be its length.
   392.  The  sparks and shocks given by long wires
and by spirals are due to secondary currents induced
in the metallic conductor  at the moments of opening
and closing the circuit.   Their intensity is higher
than that of  the  current  which produces them, and 
SECONDARY  CURRENTS.       247
which, in this connection, is called the primary cur-
rent.  The phenomena belong to the same class  as
those presented by the secondaries induced in another
conductor placed  in the vicinity of the one which  is
conveying the  battery current.
  393.  These  secondary currents may be separated
from the primary  by  placing a second flat spiral of
copper ribbon over the one through  which the bat-
tery current  is transmitted,  as  represented in  Fig.
166.   Two  wires being connected  with the  cups
                     Fig. 166.
belonging to  the  upper spiral, rub  their ends  to-
gether  while  the circuit  through the lower  one is
rapidly  broken.   Sparks  will  be seen, and  slight
shocks may  be felt through the fingers, or by placing
the wires in  the mouth.  When the  ends  of  the
wires are joined, the sparks and snaps given by  the
spiral connected with the battery are considerably
diminished,  and  no shocks can be obtained from  it.
  394.  Connect the cups  of  the upper  coil with a
delicate galvanometer,  such  as that represented  in
Pig. 39.   Whenever the battery circuit is completed
through  the lower  spiral, the  magnetic  needle is 
248
DAVIS ' S  MANUAL.
deflected to a considerable  extent, but  immediately
returns  to  the meridian, indicating  the flow  of a
momentary  current through the wire of the galva-
nometer.  On opening the circuit, a similar transient
deflection occurs in the opposite direction.  There is
no  deflection  while the  battery current is flowing
steadily.  Care should be taken that the galvanom-
eter  is  placed at such  a distance  from the  lower
spiral, that its needle may be unaffected  by it.   The
spiral is able  to deflect  a delicate needle at a con-
siderable distance, in the manner described  in <§> 276,
and if the galvanometer  is found to be at all affected
by making  and breaking contact with  the battery,
when unconnected with the upper spiral, it must be
farther  removed.
  395.  A sewing needle will be magnetized if placed
within a helix of  small  internal  diameter connected
with the upper spiral.  The polarity produced by the
current  which attends the completion of the circuit,
is  the  reverse of  that  communicated  by  the  one
attending its interruption.  If both currents are  al-
lowed to act  on  the  needle, it acquires little  or  no
magnetism,  as  they flow in opposite directions,  and
neutralize each other's influence.   The  helix should
consist  of a single length of wire, wound  so as  to
form eight or ten layers of coils, to enable it to be
used  with  currents of  considerable intensity.   Its
power will  be greater if its internal diameter is very
small.
  396.  As was stated in $ 392, the momentary waves
of electricity excited by electro-dynamic induction in 
SECONDARY  CURRENTS.        249
a conductor conveying a current, or in a neighbor-
ing one,  are termed secondary  currents.  The wave
which accompanies the closing of the circuit is termed
the initial secondary, and flows in the opposite direc-
tion to that of the current  which  induces it.  The
other, which follows the opening  of the circuit, is
called the terminal secondary,  and  flows in the same
direction as the  inducing current.   These currents
were  discovered  by Professor  Faraday,  in  1831.
They are,  probably, occasioned  by  the  disturbance
of the natural electricity of the wire by the influence
of the primary current.
   397.  In Fig. 167, a coil of fine insulated wire, W,
is  represented placed over  a flat spiral,  A, one  of
                     Fig. 167.
whose screw-cups is  connected by a wire  with the
cup P, attached to the platinum plate of a single pair
of Grove's  battery.   A  wire from  the cup  Z, be-
longing to the zinc plate, is drawn  over a steel rasp
resting on the other cup  of the  flat spiral, for the
purpose of breaking the circuit rapidly.
  398.  The ends of the wire coil, W, being fixed in
the screw-cups of  the metallic handles  shown in the 
250
DAVIS'S  MANUAL.
cut,  powerful  shocks will be  felt when  these are
grasped in the hands, and the wire connected with Z
drawn over the rasp.  In  order to  obtain the initial
and  terminal shocks  separately, the  current  should
be  broken, not  by means  of  the rasp, but  by  a
cup  containing  mercury, into which  one of the bat-
tery wires can  be dipped at pleasure.   The mercury
should, of course, be connected by a wire  with one
of the cups  attached  to the  flat spiral.
  399.  When  a battery of a single pair of plates is
employed, the  initial  secondary is much inferior  in
intensity  to  the terminal,  and  consequently gives  a
feebler  shock.   Professor Henry7 discovered that the
intensity  of the terminal  current  is  very  little in-
creased by adding to the number of pairs; the slight
increase which  occurs is due to the greater quantity
of electricity transmitted by  the ribbon spiral, when
the  intensity  of the battery  current  is  increased.
With the  initial secondary it is different; every ad-
ditional pair is found to raise  its  intensity, so that
with about ten  pairs it equals, in this  respect, the
terminal,  and with a larger number excels  it.   The
initial shock may also be  increased,  though  not  in
any  great degree, by employing a shorter flat spiral,
as, for instance, one fifteen or twenty feet in length,
with a single pair of plates.   In  quantity, as  indicated
by the galvanometer,  the two secondaries are equal;
those of the wire coil  being inferior in this respect to
the currents afforded by  a ribbon coil.
  400.  The coil represented at W  contains three
thousand  feet of copper wire, about one-fiftieth of an 
     DOUBLE  HELIX AND  ELECTROTOME.  251

inch in diameter, wound with thread;  the layers are
firmly cemented  together  by shellac,  careful insula-
tion being  requisite,  in consequence  of the length
of  the  wire and the  high intensity of  the  current
obtained.   Where a small  battery is used, this length
of wire is unnecessary, as the shock  given by it  is
scarcely greater than that from a coil of one thousand
feet.   With a larger  battery, the longer  one  will be
much superior.   A sewing  needle may be magnetized
by  the currents from a long wire  coil, as well as by
those from a flat spiral.  If the wire is fine and very
long, this effect will be diminished.
   101.  Instead of flat coils, long helices of insulated
wire may be employed for obtaining  the secondary
currents, though with less effect when not aided by
magneto-electric induction.   Several of the magneto-
electric instruments,  which,will  be described under
the next head, may be used for this purpose, the  iron
bar or bundle of  wires being withdrawn  from the
helices.  A description of  one (the double helix  and
electrotome) may properly  be introduced  in this con-
nection.
  402.  Double Helix and Electrotome.—In  this
instrument,  represented in Fig. 168,  the double helix,
a a, is confined to the base board by three brass bands.
The inner helix  is  composed of  several strands of
large  insulated  copper  wire.   The  similar ends of
these strands at  one extremity of the  helix are con-
nected with the screw-cup c.   Their other ends are
soldered to  the middle brass band, which  is  sur-
mounted by a  brass cup,   e,  for holding  mercury. 
252
D A V I S ' S  MA N U A L .
Into this cup descends a copper wire attached to the
wire w  w, which,  by means of clock-work  set in
motion by a concealed spring, is made to dip its ends
alternately  into the glass cups, G, G, which are  to
contain  mercury.   The cups being open at the bot-
tom, the mercury is brought in connection  with the
outer brass bands, upon which  they are fixed.  Both
these bands are connected with a screw-cup c', cor-
responding to c, but not seen in the cut.  A  second
helix, consisting of about two  thousand feet  of fine
insulated wire, encloses the one just described, but is
insulated from it;  its  ends are  soldered to the screw-
cups to  which the handles, seen at H, are attached.
  403.  The cups c and c' being connected  with the
galvanic battery,  the  current will pass  through  the
2353485353485353232323 
     DOUBLE  HELIX AND  ELECTROTOME.  253

inner helix whenever  either end  of  the wire w  ic
dips  into  the  mercury, which should stand at such
a height in the cups that both extremities of the wire
shall not be immersed at the same time.   By turning
the milled head, d,  the spring is wound up, and the
wire is made  to vibrate rapidly.  When either end
leaves  the  mercury, the flow  of  the current is inter-
rupted, and a bright spark is seen in the cup.  If the
handles are grasped with  moistened hands,  strong
shocks  will be felt  whenever the  circuit is broken.
Introduce into the  helix a  brass tube, and the spark
becomes small and  the shock feeble ; if the tube is
sawn open in  the direction  of its length, it no  longer
produces these effects.
   404.  When an iron bar or a bundle of soft  iron
wires  is introduced  into the  helix, the  brass  tube
being withdrawn, the brilliancy of the sparks and the
intensity  of the shocks  are  greatly increased,  the
instrument being, under these circumstances, one of
the most  powerful  belonging  to the  department of
magneto-electricity.
   405.  We have seen that a battery current of  con-
siderable quantity and low intensity can  induce either
a  quantity or  an intensity  current.  By substituting
for the  ribbon spiral, through which  the battery cur-
rent is transmitted, a coil consisting of  one thousand
feet  or more  of fine insulated wire,  and  connected
with a battery of a number of pairs, it will be found
that an intensity current is able to  induce secondaries
of intensity in  a  wire coil,  and  of quantity  in  a
ribbon  coil.
              22 
254
DAVIS'S  MANUAL.
  406.  The shocks obtained when the body is intro-
duced  into  the circuit of a voltaic battery of a con-
siderable number of pairs, without a  coil, appear to
be due to secondary currents induced in the battery
itself.  During the uninterrupted circulation of the
galvanic  current through the body, little or no effect
is perceived; but at the moment of either opening or
closing the  circuit, a shock is  experienced.  When
the series is very extensive, a dull pain is felt during
the continuance of contact.   The primary  current
has sufficient intensity to traverse the body, though
not  to  give shocks, and doubtless  induces initial
and  terminal secondaries  when it  commences  and
ceases  to flow.
  407.  A flat  spiral being in  connection  with the
battery, let  a fine  wire coil be placed at a  little dis-
tance above it; shocks may now  be obtained  from
the wire, but their intensity  diminishes in  a rapid
ratio as the distance between the coils  is increased.
With  the   arrangement  represented  in Fig.  169,
shocks through the tongue are readily obtained when
the wire coil is a  foot or two above  the other;  and
the distance  may be still further increased by using
a larger ribbon coil or  a more powerful  battery.
This furnishes a convenient mode of regulating the
intensity of the shock  at  pleasure; the same effect
is  produced  when  one  coil lies  upon the other, by
sliding the  wire coil from its central position more or
less beyond  the edge of the flat  spiral.  The shocks
are in  any  case  much  increased by  wetting the
hands, especially with salt  water.  If, however, the 
SHOCKS  VARIED.
255
quantity of  the  secondary current  is very small, the
shock is lessened by improving the conducting power
of the skin.   This may happen when  the secondary
coil consists of  very  fine  wire  and the battery cur-
rent is  feeble.
   408.  The intensity of the shocks diminishes rap-
idly as  the wire  coil  is raised  from a horizontal
position into an  inclined one; and when it reaches a
vertical position, its edge resting  on the ribbon coil,
they are no longer felt.   Similar phenomena are pre-
sented  when  the flat spiral has  a sufficiently  large
central  opening to allow the wire coil  to pass within
it; no  shocks being  obtained when their axes are at
right angles to  each other.   If the diameter of the
wire coil is considerably less than  that of the open-
ing, and  it  is placed in a horizontal  position within
the spiral, the shocks  are somewhat  stronger when
it is  near the  side than when in the centre.
   409.   The interposition of any good conductor of
electricity between  the fine wire coil and the one
           p.  169        connected  with  the  bat-
                          tery nearly neutralizes the
                          shocks.   The coils  being
                          arranged as represented in
                           Fig. 169,  interpose a slip
                           of wood or a plate of glass
                           between  A and  W, and
                           the  shock will be the same
                           as  if air only intervened.
 This will be the case with any non-conductor of elec-
 tricitv.   Now,  interpose a plate of metal, for instance,
 
256
DAVIS'S  MANUAL.
lead or zinc, one tenth of an inch thick, and as broad
as the coils.  The shock  will be so much reduced as
to be scarcely  perceptible.   If  the  interposed plate
is broader than the coils, the reduction in the shock
is still  greater.   The magnetizing power of the cur-
rent is also lessened, in respect  to hard steel; thus,
a sewing needle, placed within a  helix, will  be  but
feebly charged.   A  certain thickness of metal is re-
quired to produce these effects,  as several sheets of
tin foil may be interposed without  diminishing  the
shocks in any  appreciable degree.
   410.  The interposition of a metallic plate does not
prevent the occurrence of the secondary currents, but
causes a great  reduction in  their intensity.  That
the  quantity of the  current is not affected,  may be
shown by connecting  the ends  of the  upper coil,
especially if it  be a  ribbon coil instead of a wire one,
with a galvanometer.   The deflections will be the
same whether the plate is interposed or not, provided
the  distance between  the  two  coils is  not  altered;
but  when the plate is  of  iron,  the  deflections are
somewhat diminished.
   411.  In Fig. 169, M represents a metal plate, from
which a slip is cut  out in the direction of a radius,
the cut extending to the  centre.    When such a plate
is interposed between  the coils, the shocks are not
at all lessened.   Instead of a metallic plate, interpose
a flat spiral  between the battery coil and the wire one.
No diminution of the shocks will be perceived.  Now,
connect  the  cups of the  interposed coil  by a wire,
and the  intensity of the  shocks will  be even more 
           SECONDARY  CURRENTS.       257

reduced than  by a  plate of metal.  Whenever the
shocks are diminished, the brilliancy of the sparks
given by the battery spiral are also  lessened to some
extent.
  412.  Secondary  currents  may also be  obtained,
without breaking the primary circuit, by altering the
quantity of the battery current  or  the distance be-
tween the coils.  A flat spiral  being connected with
a single  pair of plates, place a second spiral of the
same kind upon it, with its cups in connection with
a galvanometer.  While the  current is flowing stead-
ily through the lower  spiral, no secondary is excited,
and  the needle of  the galvanometer is unaffected.
Now, lift one  of the plates of  the battery partly out
of the liquid.   The moment the  plate begins to be
raised, the needle  moves in the same direction  as  if
the  circuit were broken ; the deflection,  however, is
not  momentary, as in  that case, but continues during
the  movement of the  plate.   Then, without taking
the  plate out of the solution, which would  break the
circuit, depress it  again.   The  galvanometer  will
now indicate  a current in the opposite direction  to
the  former one.
   413. Similar currents are produced by raising the
upper coil from the lower one, through  which the
galvanic  current  is steadily flowing.   As the coil
recedes, a secondary  flows  through it  in  the  same
direction as that of the battery current in the other
spiral;  as  it again  approaches, a current in the
reverse direction  is induced.  Instead of raising the
upper spiral,  it  may  be  moved laterally  from  its
              22* 
258
D AVI S ' S  MANUAL.
central  position on  the  lower  one with  the  same
result.
  414.  These currents produce a greater effect upon
the galvanometer than  those excited by closing and
opening the circuit,  as  they are not momentary, but
last  as  long as the motion continues.  The  more
rapid the  movement of the battery plate,  or of the
spiral, the more  powerful are the  secondary currents,
as they depend  upon the suddenness of the  change
in the quantity of  the  primary  current in the one
case,  and in the distance between the coils in the
other.   They  are,  however, of  low intensity, and
are unable to afford shocks.   The  interposition of
metallic plates or coils produces no effect upon them.
  415.  The neutralizing action  described in <§> 409
and § 411, is due to a secondary current excited in the
interposed  metallic  plate or spiral, which  itself in-
duces a tertiary current in  the wire coil, flowing in
an opposite direction to the secondary induced in it
by  the  battery  current,  and therefore retarding its
development.   A tertiary current is also induced in
the battery coil, which  occasions the reduction in the
spark and shock noticed in  <§> 393 and <§> 411.   When
the interposed plate of  metal is divided to  its centre,
no secondary  is induced in it, and  it exerts no neu-
tralizing action ; the same is the case with the ribbon
spiral in  $ 411, when  its cups are disconnected.
Similar phenomena are produced  by the introduction
of a  metallic tube  into a  wire  helix,  as  described
in $403.
   416.  This  tertiary current can be  separated from 
TERTIARY  CURRENTS.        259
the secondary, and obtained by itself, in the following
manner.   A ribbon coil B (Fig. 170) being laid upon
                      Fig. 170.
the coil  A, through  which the  battery  current  is
transmitted, connect its cups with  those  of a  third
spiral, C, of the same  kind, removed to a little dis-
tance, so as to be beyond  the influence of the cur-
rent in A.  The secondary  current induced in B will
now flow through C, and if a fine wire coil, W, is laid
on C, strong shocks may be obtained.   If W is raised
up. the shocks  are still felt  when  it is at a consider-
able height above C.
   417.  By placing a fourth ribbon coil on C instead
of the wire coil, a quantity current  will be obtained,
capable of affecting the galvanometer slightly, and
of magnetizing a sewing needle placed in a helix  of
small internal  diameter.   Let two  fine wire coils  be
substituted for  the flat spirals B and C.   A secondary
intensity current will now be obtained, which will
induce a tertiary of intensity in a third wire coil laid
on the second,  enabling it to afford  strong shocks,  or
a  tertiary  of quantity  in a ribbon  coil.
   418.  If the  second  spiral, B, is  alone replaced by a
wire coil, little or no shock can be obtained from W, 
260
DAVIS'S  MANUAL.
the quantity of the secondary current furnished by
the wire coil not being sufficient for the production
of a powerful tertiary, unless it  is passed through a
conductor of many convolutions.  So, on  the  other
hand, if a fine wire coil is substituted for C only, no
tertiary is induced by it, or at most a feeble one, the
secondary current from  B not having  sufficient in-
tensity to enable it to  overcome the resistance of the
long wire.   The tertiary current, like the secondary,
can be induced at  a  distance, and has its intensity
greatly reduced by the interposition of metal between
the flat spiral C  and  the  wire coil.
  419.  The tertiary  currents may be conveniently
obtained by causing   the  secondary from  a ribbon
spiral to flow through the inner  helix  of the instru-
ment represented in Fig. 168, or  of almost any of the
magneto-electric instruments, which will be described
under the next head.   Thus, if the wires attached to
B, in Fig. 170, are  fixed in the  cups c and c' of the
double helix and electrotome, strong shocks may be
obtained from the tertiary current induced in the
fine wire helix.   The circuit through  the  inner coil
should not be broken  by the electrotome, as the only
interruption  wanted  is that in  the battery current.
The shocks  are increased by placing a bundle of iron
wires within the helix, as the inductive action of the
current is then assisted by that of the electro-magnet.
  420.  Tertiary currents,  like  secondaries,  are in-
duced  both  when the primary circuit is opened and
when it is closed.  The initial and terminal tertiaries
both flow  in the opposite directions  to  the  corre-
sponding secondaries.   In  fact, each  secondary must 
            TERTIARY  CURRENTS.        261

produce two tertiaries, one when it commences, and
another when it ceases to flow j  but in consequence
of the exceedingly short duration  of the  secondary
itself,  they cannot  be separated  as the initial and
terminal secondaries can; and the current which is
obtained is only  the  difference between  the  two.
This  accounts for the  slight effect it produces upon
the galvanometer, while capable of affording strong
shocks.  The two parts  may differ very  much  in
intensity, but, being equal  in quantity,  would not
affect the galvanometer, did  they occur  precisely  at
the same  instant.   The needle, however, is  first
deflected by the momentary  wave  induced by the
commencement of the  secondary, and, as soon as it
has moved a degree  or two,  is  arrested by the
Wave  due to its cessation, and carried in  the oppo-
site direction.
  421.  The effects of the  interpositions described
in <§> 409 and $ 411 may now be more fully explained,
The secondary induced in the interposed conductor,
on opening the primary circuit, itself induces a terti-
ary in  the wire coil at the instant of its commence'
ment, which flows against the secondary induced  in
it by  the  battery current.   When  the secondary  in
the interposed body ceases, another tertiary is excited
in the wire  coil  flowing  in the same direction as the
secondary.   The total  amount of the current is not
altered, since the same  quantity is added at  its ending
as was subtracted at its beginning; but its intensity-
is greatly reduced, probably  in consequence of th(
diminished rapidity of its development, 
262
DAVIS'S  MANUAL.
  422. Currents  of higher Orders. — It has been
shown that a secondary  current, though only mo-
mentary  in its duration,  can  induce a  tertiary  of
considerable energy.  It might therefore be expected
that the  tertiary  would  produce a  current  of the
fourth  order;  this another, and so on;  and such is
found to  be the case.   It is only necessary to remove
the tertiary out of the influence of the secondary, in
the same manner  as  the secondary is removed from
that of the primary (see $ 416), in order  to obtain a
current  of the fourth  order.  The  currents of the
third, fourth, and  fifth  orders were first obtained  by
Professor Henry,  and  two other orders  have been
since  added.   These currents progressively diminish
in energy, but the phenomena presented by them are
similar to those of the tertiary.   With a larger num-
ber of coils and a powerful battery,  the series might
doubtless be extended  much farther.
   423.  In the following  table, the  directions of the
currents  produced both at the  beginning and ending
of the battery current are  given ; those which flow in
the same direction as the  primary being indicated by
the sign  -f-,  and those in the opposite direction  by
the sign  —.
                            At the beginning.  At the ending.
	.. + ...	••■ +
		■•• +
	.. + ...	
	. . — ...	. . . +
	.. + ...	
Current of the sixth order, . .		.. .+
Current of the seventh order, .	.. + ...	
 
      currents   of  higher  orders.  263

If the induction at  the ending of the  battery current
is regarded as opposite  to that at the  beginning, the
second column may commence  with  minus instead
of plus,  and the second series  will  then alternate
like  the  first.
  424.  Induced currents of the  different orders may
be obtained from frictional electricity, though, in con-
sequence of its high intensity, the conductors require
better insulation  than  is necessary when they are
used with the galvanic  battery.  The  flat  spirals and
wire coils may, however, be employed, if their layers
are  carefully insulated by  means of shellac, or if
covered with  silk instead  of cotton.
  425.  Let a fine  wire coil  be placed over a ribbon
spiral, with a  plate  of glass interposed; a secondary
shock may now be  obtained  from the  wire when the
charge of a Leyden jar is passed through  the  spiral.
A still better mode is to employ a second wire coil,
instead of the flat spiral ; if the  ends of one of the
coils are  held in  the hands, a strong  shock will be
felt at the moment of discharging the jar through the
other.  The  secondary current  flows in  the same
direction as the one which  induces  it; as  may be
shown by passing  it through a  helix consisting of
several layers of coils, when it will magnetize  a
sewing needle placed within it. 
264
DAVIS'S  MANUAL.
     II.  BY THE INFLUENCE  OF A  MAGNET.

  426.  The  name  of Magneto-Electricity is given
to that branch of science which treats of the develop-
ment of electricity  by  the influence  of magnetism.
Electric  currents   are  excited  in a  conductor of
electricity  by magnetic changes taking place in its
vicinity.  Thus the movement of a  magnet near  a
metallic wire, or near an iron bar enclosed in a  wire
coil, occasions currents in  the  wire.   They are  also
produced  at  the moment  of commencing  and  sus-
pending the  flow of a  galvanic current through the
coil surrounding an electro-magnet.   In this case, an
induced current may be  obtained  either from the
wire  conveying the primary current, or from a sec-
ond  wire also surrounding  the iron;  but the current
excited by the  influence  of the  magnetized bar  is
obtained in connection with  that which is the result
of electro-dynamic  induction, and cannot be separated
from it, at least with the  usual arrangement of the
wires.  The  discovery of the induction of electricity,
both by steel magnets and by electro-magnets,  was
made by Professor  Faraday, in 1831, during the  same
course of experiments which  led to the discovery of
electro-dynamic induction.
   427.  Let  the heliacal ring  (<§>271) be  connected
with a  gold leaf galvanoscope, as represented in Fig.
171.  By  passing the ring over one  of the poles of
a steel U-magnet, the gold  leaf will be  sensibly 
MAGNETO — ELECTRICITY
265
deflected during the continuance of the motion.  On
withdrawing the ring  from the pole, a deflection in
                                the  opposite  direc-
            Fig. 171.
                                tion will occur, and
                                in the same  direc-
                                tion as that obtained
                                by passing it over
                                the other pole. The
                                heliacal ring may be
                                connected  with  a
                                delicate galvanome-
                                ter, such  as  is de-
                                scribed  in $ 162,
                                with  the  same re-
                                sult.
                                  428.  If the he-
 lix represented in Fig. 107  is  connected with the
 galvanometer,  and a bar magnet or one pole of a U-
 magnet  is introduced into it, the needle of the gal-
 vanometer is deflected while the magnet  is passing
 in, but returns to its  former  position as soon as the
 magnet  is at rest within the  coil.  On drawing the
 magnet  out, the  needle is deflected in the opposite
 direction.   By moving the magnet in  and out so as
 to keep  time with the oscillations of the needle, they
 are  greatly  increased.  Reversing  the direction  of
 the  magnet, so as to make  it enter by the contrary
 pole  reverses the indications of  the  galvanometer.
 If the bar magnet is carried through  the  helix, and
 brought out at the opposite  end to that by which it
 entered, the effect is the same as if it had been drawn
               23 
266
D A VI S ' S   MANUAL.
out at the same end.   No  current is excited  while
the magnet and  helix are both at rest.
   429.  Connect the cups of a flat spiral (Fig. 112)
with  the  galvanometer,  and pass a  U-magnet over
it, towards the centre, with one of its poles above and
the other below.   The  needle  will  be  deflected  in
opposite  directions as  it passes on and  off.   A less
effect will be  produced by moving a bar magnet  in
the direction of a radius over the spiral, or by passing
it  into the central opening.
   430.  Place a  bar  of soft iron within  the  helix
(Fig. 107), and connect its cups with  those  of a
galvanometer.   Then  bring either  pole of a  steel
magnet in contact  with one extremity  of the iron.
The bar  instantly  becomes magnetic, and the gal-
vanometer needle is deflected  by the current pro-
duced  by this means in the helix.  It, however, im-
mediately returns to its  former position, the settled
magnetic  condition of the  bar  having no power  to
excite  a  current.  On  withdrawing  the magnetic
pole, the  bar loses its  magnetism, and the needle is
deflected  in the opposite direction.
   431.  By alternately bringing the magnet in con-
tact  with the iron, and withdrawing it in such a
manner as to  keep time with  the vibrations  of the
needle, they may be greatly increased.  If the  oppo-
site poles  of two bar magnets are  brought in contact
with the ends of the iron bar, and especially if their
other poles are made to  touch, so that the two magnets
form the  letter V, the  inductive influence  is  much
greater.   By  opening and  shuttmg the  magnets,  as 
MAGNETO — ELECTRICITY.       267
if joined by a hinge at the vertex, the magnetism of
the  bar within  the helix may be  communicated and
removed at  pleasure.
  432.  When an armature or any piece of soft iron
is brought  in contact with one or both of the poles
of a magnet, it  becomes itself magnetic by induction,
and by  its reaction adds to the power of the magnet.
On  the contrary, when taken away, it diminishes the
power of  the magnet.   This alteration in  its mag-
netic  state induces a current of  electricity in a  coil
surrounding it, as may be shown by passing a wire
coil, whose  ends are connected with a galvanometer,
over one of the poles of a U-magnet, as represented
in Fig. 171, keeping the magnet and coil stationary.
The  needle will now be  deflected  in  one  direction
when an armature is applied to the  poles, and in the
opposite direction when it is removed.
   433. The most  powerful effects  are obtained  by
causing a bar of soft  iron, enclosed  in a  helix, to
revolve, by mechanical means,  near the poles of a
steel  magnet.  The principle may  be  illustrated by
connecting the cups, A and  B, of the revolving elec-
 tro-magnet  (Fig. 146) with a delicate  galvanometer,
 as  represented  in Fig. 172.  On  causing the iron bar
 to  rotate rapidly, by drawing the hand over the axis,
 the needle  is powerfully deflected.   As the iron ap-
 proaches  the poles  of the steel  magnet, it  becomes
 magnetic ;  as  it recedes from them,  its magnetism
 disappears.  While one end of the bar is leaving the
 north pole, or approaching the south pole, the electric
 current flows in a constant direction, the loss of south 
268           DAVIS'S  MANUAL.
polarity by  the iron,  and the production of  north
tion.  During the other half of the revolution,  the
same  end of the bar is approaching the north pole
or receding from the south, and a reverse current is
produced.  The two currents are  conveyed  to  the
galvanometer in one direction by means of the pole-
changer on the axis of the revolving bar.   The pole-
changer, in place of altering the direction of a current
conveyed to  the coil,  as it  does when the  bar is
made  to revolve by a galvanic battery, here performs
the duty of bringing two opposite currents from  the
coil into one  course.   The  current traversing  the
wire of the galvanometer is, consequently,  not  re-
versed,  except  by  changing the  direction  of  the
rotation. 
MAGNETO —ELECTRIC  MACHINE.   269
  434.  If the cups A and  B are connected with the
cups c and c' of the double helix and electrotome,
slight secondary  shocks, which may  sometimes be
felt in the hands, will be obtained  from the fine wire
helix by rotating the iron  bar, as  in  the  cut.  The
hollow of the double helix should  be  filled with iron
wires, and the vibrating wire  be  put in motion so
as to break the circuit rapidly.
   435.  With  a  sufficiently delicate  galvanometer,
any of the electro-magnetic  instruments in which
motion  is produced by the mutual action between a
galvanic current and a steel magnet, may  be made to
afford a magneto-electric  current by  producing  the
motion  mechanically.   In all  cases, the current  ex-
cited flows in the opposite direction to the galvanic
current which would be required to produce the same
motion.
   436.  When a galvanometer is  used in these  ex-
periments, it must be placed at such a distance from
the instrument where the movements and magnetic
changes are  made, that  the  needle shall not be de-
flected  by any  influence but  that which reaches it
through the  connecting wires.  With the gold leaf
galvanoscope  this precaution is unnecessary.
   437.  Magneto-Electric Machine.—In  the in-
strument represented in Fig.  173, an armature, bent
 twice at  right angles, is made to revolve rapidly, in
 front of the poles of a compound steel magnet of the
 U form.  The  U-magnet, whose  north pole is seen
 at N is fixed in a horizontal position, with  its  poles
 as near the  ends of the armature as will allow the
              23* 
270
D A VI S ' S  MANUAL.
latter to rotate without coming in contact with them.
The armature is mounted on an axis, extending from

                     Fig. 173.
the pillar P to a small pillar between the poles of the
magnet.   Each of its legs  is enclosed in a helix of
fine insulated wire.  The upper part of the pillar P
slides over the lower part, and can be fastened in any
position by a binding screw.  In this way the band
connecting the two  wheels may  be  tightened at
pleasure  by increasing  the  distance between  them.
This  arrangement also  renders the  instrument  more
portable  than would otherwise be  the  case.
  438.  By means of the multiplying wheel W, which
is connected  by the band with a small wheel on the
axis, the armature is  made to revolve rapidly, so that
the magnetism induced in it by the  steel magnet
is  alternately  destroyed and renewed  in  a  reverse
direction to the  previous one.  When the legs of
the armature are  approaching the  magnet, the one
opposite the north pole acquires south  polarity, and 
M AG N E T O —E L E CT R I C CURRENTS.  271
the other north polarity. (See $ 228.)  The magnetic
power  is the greatest  while the  armature  is passing
in front of the poles.   It gradually diminishes as the
armature leaves this position, and  nearly  disappears
when it stands  at right angles with the magnet.  As
each leg of the armature approaches the  other pole
of the U-magnet, by the continuance of the motion,
magnetism is again induced in it, but in the reverse
direction to the previous one.
   439.  These  changes in the magnetic state of the
armature excite electric currents in the surrounding
helices, powerful in proportion to  the  rapidity with
which  the  magnetic  changes are  produced.   The
helices are so connected as to  form a continuous coil.
The ends  of this coil  are soldered to  the segments
of a pole-changer (Fig. 70), secured on the  axis.
Two  silver springs  press  upon   these  segments,
and  convey the electricity to the  two screw-cups.
Although the  currents in  the helices are reversed
twice  in each  revolution, they are turned into one
direction  by means of the pole-changer.   From the
manner in which they are obtained, they  necessarily
vary more  or  less in  power  in  the  different  parts
of the  revolution,  according  to  the position of the
armature.
   440. This  primary magneto-electric current has
too  low an intensity  to  afford strong  shocks.   But
secondary currents may be obtained by interrupting
the  primary circuit,  as  with the  galvanic current.
(See $392.)   These  have a much higher intensity,
and give powerful  shocks.  One of the springs press- 
272
DAVIS'S  MANUAL.
ing on the pole-changer is fixed  by a binding screw
m B,  and the other in a similar pillar opposite to B.
They are bent at right angles, and when both  the
horizontal and vertical portions  are made to touch
the segments of  the  pole-changer, the  circuit is
broken  as the armature revolves.   The horizontal
parts simply bring the two primary currents into  one
course.   For showing the sparks, another wire-spring,
fixed  in the  pillar, B, is made to play upon steel pins
set in the small wheel on the shaft.
   441.  Shocks are  obtained  at every  part of  the
revolution;  but,  with  a  moderate  speed, they  are
most  powerful when  the  legs of  the  armature  are
near the magnet.   If  the  motion is very rapid,  this
difference is less  appreciable, and  with a powerful
machine,  the torrent of shocks  which  then results
becomes insupportable.  The muscles of the hands
which grasp the handles are involuntarily contracted,
so that  it  is impossible  to loosen  the  hold.   The
shocks  are,  however, instantly suspended by bring-
ing the  metallic  handles into  contact.   A spark is
seen when the wire fixed in the  pillar B leaves each
of the  pins on the wheel.
   442.  In  Fig. 173, the metallic handles are repre-
sented in connection with the screw-cups, for the pur-
pose of giving shocks.   When these are held in the
hands, the arm connected with the negative cup  will
be found most affected by the  shocks.  This  is a
physiological  phenomenon, the current  producing a
greater effect upon the arm in  which it  flows down-
wards,  in the direction  of the  ramification of the 
      MAGNETO-ELECTRIC  SHOCKS.    273

nerves, than upon the one in which it ascends.   The
initial  secondary is  too feeble  to  afford  shocks,  so
that  only the terminal secondary need be taken into
account.  The  intensity  of the terminal shock  is,
however,  constantly varying,  according to the  posi-
tion  of the armature  in respect to  the magnet, and
the difference  in the effect upon the two arms  is not
so distinctly marked as  with some of the instruments
which will  be described  hereafter.
   143.  The shocks may  be  regulated to some ex-
tent, by varying the speed with which the  armature
is made to revolve.   They are considerably lessened
by partially neutralizing the power of the steel mag-
net, by placing an armature across  it near the  poles;
also,  by passing the  current through  a piece of wet
cotton wicking, a few inches long, one end of  which
is connected by a  wire with one of the screw-cups
on the base  board,  from  which the handle  is  re-
moved.   By grasping in  one hand the handle con-
nected  with the other screw-cup, and in  the remain-
ing  hand the disconnected  handle,  and touching a
short wire  attached  to this to the wet  cotton, the
shock is  diminished  in proportion to the length of
the imperfect  conductor which the current is obliged
to traverse.   The handles represented in  Fig. 173
are  of  German silver.    Between  the metallic  part
of each handle and the screw-cup attached to it, is
 interposed a cylinder of wood.   No shock is felt when
one or  both are held by the wooden portions.
   441.  Slight  shocks may  be obtained  from  the
 primary  current,  by  grasping  the metallic handles 
274
DAVIS'S  MANUAL.
connected with the screw-cups.  The wire at B, which
plays upon the  pins, must  be  removed, so that  the
circuit shall  not be broken.   It  is  also essential
that neither  of  the springs pressing  on  the  pole-
changer should  leave the segment  which  it touches
before it comes in contact with  the opposite segment.
If this  is neglected, the  circuit  will be interrupted
at the  pole-changer,  and  strong  shocks   obtained.
When the screw-cups are connected with  those  be-
longing to the  inner  coil of the double  helix and
electrotome (<§> 402), and the central opening of that
instrument is filled  with iron wires, secondary shocks
of considerable  strength will be obtained  from  the
exterior helix whenever  the armature  is  made  to
revolve.   The vibrating wire should be put in mo-
tion to break the primary circuit.   Bright  sparks are
at the same  time  seen in the  mercury cups.   The
magneto-electric sparks are  conveniently  shown by
passing the primary current of  the  machine through
the  clock-work  electrotome  (Fig.  165),  the vibrat-
ing  wire  of  that instrument being  set in  motion.
   445.  When the  primary magneto-electric current
is made to pass through water in a constant direction,
the water is resolved into its elements,  and the gases
hydrogen and oxygen  are  given off separately,  by
the  two  wires  which convey  the  current.  Two
platinum  wires being connected with the screw-cups,
and their ends immersed in water, a slender stream
of gas will be seen to  escape  from each wire when
the armature is  made to revolve.   The decomposing
cell, represented in  Fig. 28, is well adapted  to  this 
    MAGNETO-ELECTRIC DECOMPOSITION. 275

experiment.  A little sulphuric acid may be added
to the water, but care should  be taken not to make
the conducting  power too great,  or  the  amount of
gas evolved  will be lessened.
   446.  The experiments described under the head
of Galvano-Decomposition (<§> 66 to <§> 70) may be per-
formed  with the magneto-electric  machine,  though
the effects  are  on a smaller  scale.  The  primary
current  is  preferable to  the secondary for  this pur-
pose.   Strips of platinum  foil,  which are generally
superior  to wires in decomposing  by a  compound
galvanic battery, do not answer  so  well with  the
magneto-electric current, especially  when  the wire
coiled upon  the armature  is fine.
   447.  Let the decomposing tube (Fig. 31) be filled
with a weak solution of iodide of potassium, with-
out  any  coloring  liquid.  By causing  the  arma-
ture to revolve, iodine  will be abundantly liberated
round the  positive wire ; this,  being slightly  soluble,
gives a brown color  to the  liquid, but most of it
remains in suspension, forming a  dense  cloud.  If a
few drops of  a weak  solution of starch had been
previously  added,  an  intense blue  color  will  be
developed.
   448.  When  a solution of  sulphate  of copper is
employed, sulphuric acid and oxygen are set free in
the positive cell, and metallic copper is  precipitated
upon the  negative wire.   If the current  is powerful,
it is deposited as a slightly adherent black  powder;
but if of moderate  strength, a thin coating is formed,
possessing  the  proper  color and  appearance of  the 
276
DAVIS'S  MANUAL.
metal.   In this  case  little or no hydrogen escapes
from the coated wire, though oxygen is given off by
the positive  one.    On  reversing  the  current,  the
copper is gradually dissolved off from the coated wire,
and a similar deposit occurs on  the other.  No oxy-
gen escapes from  the wire which is  now positive,
until its coating has nearly disappeared.  When the
experiment is concluded, the  deposited copper may
be  removed  from  the  platinum wires by a  little
diluted  nitric acid.  If two  copper wires are im-
mersed  in the  solution, as much copper  will  be
dissolved  off of one as is deposited upon the  other.
Sulphuric acid does not  act upon copper  in the cold,
unless aided in this  way  by an electric current.
   449.  Let the tube  contain a solution of cyanide
of gold (§ 102), the conducting wires being of plat-
inum.   The negative wire will  soon become covered
with a coating of gold, which increases in thickness
as the  current is continued.   Other metals, as,  for
instance,  silver, copper,  and brass, may be gilded by
attaching them to  the negative wire, and immersing
them in the  solution.  The coating does not adhere
firmly, unless the metallic surface  on which it is  to
be deposited has been perfectly cleaned, as directed
in $103.
   450.  Many other metallic salts may be decomposed
in the same manner, and the metals precipitated; but
in most cases, the deposit is of  a black color.   Both
wires may be in  the same portion of liquid, no par-
tition being  required.  The deposition of the  metals
from their solutions depends upon the same principles 
      MAGNETO-ELECTRIC  MACHINE.   277

which are concerned in the case of the galvanic cur-
rent, as explained under the  head of  Electro-Metal-
lurgy.   The magneto-electric machine is sometimes
employed in electro-gilding and silvering, in place of
the galvanic  battery.   When  the  mechanical power
requisite to maintain the motion of the armature can
be conveniently obtained,  it  may be  used with ad-
vantage; especially if the coils  are  constructed  in
the manner which  will shortly be described,  so  as
to furnish  a current of considerable  quantity.
   451.  The galvanometer is strongly  affected by the
primary magneto-electric current.   Even a large and
heavy needle, surrounded  by a single  wire, as in the
instrument represented in  Fig.  53, may readily  be
deflected.  A sewing needle, or a piece of steel wire,
placed in a magnetizing helix, will be fully charged.
When the extremities of the wire surrounding a small
electro-magnet,  such  as is represented in  Fig. 126,
are fixed in the screw-cups, it will  sustain a weight of
some ounces  while the primary current is  flowing.
If the electro-magnet  is covered  with  four or  five
layers of coils, the wire being in a single length,  it
will lift several pounds.
   452.  Improved  Magneto-Electric  Machine. —
An improved form of the machine is represented  in
Fig.  174.    Two straight armatures,  surrounded  by
coils  of  insulated copper  wire, revolve between  two
U-magnets, according  to Dr.  Page's plan ; but much
shorter armatures are used than in the machine con-
trived by  him.  The steel magnets  are fixed, with
the south  pole of  one above the north pole  of the
               24 
278
DAVIS'S  MANUAL.
other, at such a distance as just  to  allow the arma-
tures  to  pass between them.   These are  mounted,
one on each  side of a vertical shaft, in such a man-
ner that  both shall be passing between the opposite
poles  at  the  same time.   They are made to revolve
rapidly by a multiplying wheel, as in Fig. 173.  A
pole-changer on  the shaft  conveys  the  alternating
currents  in a constant direction  to  the  screw-cups
with  which  the metallic  handles are shown in con-
nection.
   453.  For  giving  shocks, the small wheel  on the
shaft  is set with  vertical  pins, upon  which plays an
iron or steel wire connected with one of the screw-
cups.  Brilliant  sparks are seen as the wire  passes
over  the  pins.  These sparks are sometimes half an
inch in  length.   The shocks are  stronger than with
the machine  last described,  and the  decomposing
power considerably  greater. 
VIBRATING  ELECTROTOME.      279
  454.  Magneto-Electric Machine,  with Vibrat-
ing  Electrotome.—In this form, the circuit is not
interrupted by  the  motion of the  machine itself, for
giving shocks; but the vibrating electrotome, which
will  be described immediately,  is attached for  that
purpose, as  represented  in Fig. 175.  The shocks
                     Fig. 175.
are  of more  uniform strength with this  interruptoi
than with the  mechanical one, as they occur only
when the primary current charges the electro-magnet
sufficiently to draw down its armature.  For sparks.
decompositions, &c, the primary current can be used
without passing it through the coil of the electro-
tome.  This is effected  by turning the screw  S, so
as to raise the platinum point from  the spring attached
to the armature.
  455.  Vibrating  Electrotome. — In  Fig.  176,
the vibrating electrotome is shown in  a form adapt-
ed for use with either of the  machines described in
$ 437 and <§> 452.   There is an electro-magnet,  of the
U form, enclosed  in  a helix  consisting of several
layers of coils.  Above this  is a  straight armature, 
280
DAVIS'S  MANUAL.
fixed  to a spring,  by which it is held  up from the
poles.  The screw-cups at one extremity of the base
                       board are to  be connected
                       with  the  cups  of  the  ma-
                       chine, and those at the other
                       end  with  the  handles  for
                       shocks.   The primary mag-
                       neto-electric current is pass-
                     _, ed through the helix, and a
m                  ^ secondary obtained by inter-
rupting the circuit  by the movement of the arma-
ture.  One screw-cup at each extremity of the stand
connects with one end of the helix,  which consists
of a rather long single wire, and the  other two cups
with the  pillar to which the armature is fixed.  The
shock is  thus obtained from  the  same  wire  which
conveys the  primary current.
   456. When  the machine  is put in  motion, the
electro-magnet is instantly charged, and draws down
its armature.   This motion depresses  the spring, and
separates a little platinum  disc upon it  from a point
of the same metal attached to a set screw, S, above
the spring.   On the interruption of the circuit, the
armature is raised by the force of the spring.   A thin
slip of brass  brazed to the face of the armature pre-
vents it from being  retained by the  poles.  The
shocks are varied to some extent,  by  turning  the
screw, S,  which alters  the  distance  between  the
armature and the  poles.
   457.  The  primary  magneto-electric current  re-
sembles a galvanic current excited by a number of
 
      magneto-electric  machine.   281

small pairs.   Its quantity and intensity are, however,
both greatly influenced  by the size and length of the
wire enveloping the armature.   A long and fine wire
affords a current of small quantity and high intensity,
and is most suitable for  giving shocks.   A short wire
of large  diameter gives a current of moderate  in-
tensity, but of considerable quantity,  and is, there-
fore, best  for producing sparks, decompositions,  and
magnetism.
  458.  Magneto-Electric  Machine, for  Quan-
tity.— The  machine  represented  in Fig.  177  is
similar to  the one described in § 452, except that the
armatures are wound with  short coils of coarse wire.
By  this arrangement,  a  quantity current is obtained,
capable of producing motion in some of  the electro-
magnetic instruments, like the galvanic current.  In
the cut, the revolving bell engine (Fig. 147) is shown
in connection with the machine.   The primary cur-
rent is  employed, and those instruments are  best
suited to the purpose which do not require a power-
              24* 
282
DAVIS'S  MANUAL.
ful current to operate  them.  Both quantity and  in-
tensity  armatures may be  adapted  to  any  of the
machines, so  that one may be  substituted for the
other at pleasure.
  459.  We now pass to a class of instruments in
which electric currents are  induced  by  electro-mag-
nets whose  magnetism is  alternately acquired  and
lost.  These instruments consist essentially of double
helices  containing bars or  wires of  soft iron.  The
magneto-electric  current  is thus  obtained  in  con-
junction with  that excited by electro-dynamic  in-
duction, and  the current formed by their union is
called a secondary, though only in  part such.
  460.  Platinum wire may be ignited  by this sec-
ondary  current in  the manner represented in Fig.
178.  A short piece  of  fine platinum wire is secured
by  binding  screws to the wires of a large electro- 
POWER  OF  BATTERIES.      283
magnet.   The  wires are  uncovered at  that  point,
and being connected by the platinum, a part of the
battery current passes through  it.   It should be long
enough  not  to be  fully  ignited  by  this-  current.
When  one of the  wires is connected with  one pole
of a single pair of  Grove's battery, and the remaining
wire brought in  contact with the other  pole, the
electro-magnet becomes charged.   On breaking con-
tact, its magnetism  instantly disappears, and  a cur-
rent  is induced  in the surrounding coil  which flows
in conjunction  with the  secondary excited  by the
battery current itself.   The  combined currents have
no circuit open to  them except through  the platinum
wire, which  is for  the  moment  ignited  by their
passage.
   461.  Since the  description of Smee's and Grove's
batteries,  in the earlier  part of the volume,  was writ-
ten,  some experiments have  been made  in relation to
them, which are of sufficient interest to be mentioned
here, though out of their proper place.   The  first
trials were made to  ascertain the relative power of a
single  pair of Smee's battery with the plates at differ-
ent distances.   The plates used were flat, and were
placed opposite to each other, in a porcelain trough,
containing sulphuric acid, diluted  with 15 times its
measure  of  water.   In the whole series of  experi-
ments,  the power was measured by  the magnetism
developed in a magnetometer (Fig. 131), through the
coil of which the  current was  passed.
   462. In the following table, the first  column gives
 the  distance of the  plates in inches and fractions of 
284
D AVI S ' S  MAN UAL.
an inch.   The second and third  columns  give  the
attractive force of the electro-magnet, or the magnet-
izing  power of the current, in grains.   The weights
in the second column were obtained with a smooth
platinum plate;  those  in the third, with one plati-
nized in the usual manner.

                    Table  I.
    Distance.         Grains.            Grains.
      10......25,000......30,000
       5......30,000......34,000
       2£.....32,500......37,500
       1}.....38,000......40,500
        |.....40,000......42,500

  It will be seen that, as the plates are approximated,
the power  gradually increases, but  not  in  any very
great  degree.   The table shows  the advantage  of
platinizing the negative plate.
  463.  With a battery  of the form  represented in
Fig.  178, the increase  of power  by  adding  to the
size of the  plates was  determined.   The negative
plate  consists of  one or  more pieces of zinc, whose
lower ends are placed  in the  mercury at the  bottom
of the battery.  The weights in Table II. were ob-
tained with  the  battery  arranged as  a Smee's, the
porous cell  being removed.   In  the first column  is
given the  number of  zinc plates, the whole being
connected as a single plate.   One piece of platinum
was employed in  the three first experiments,  and in
the fourth, two pieces, connected as one. 
POWER  OF  BATTERIES.        285
                     Table  II.
Number of Zinc Plates.                     Grains.
       1................47,000
       2................51,000
       3................53,000
       3................56,000

  464.  The  battery was  now  converted into  a
Grove's,  by  using the  porous cell, and its  power
with  different   exciting  liquids examined.   Equal
measures of sulphuric acid  and water  were poured
into the porous  cell, and to this  liquid was  subse-
quently added pulverized nitre, in portions of one
spoonful each.   The results  are  given in the fol-
lowing  table: —

                     Table  III.
             Fluid in Cell.                Grains.
      Sulphuric acid  and water, ....  50,000
      With 1 portion of nitre,.....65,000
        "   2 portions"   "......86,000
        tt   3     «     «   «......91,000

  465.  When the  porous cell was filled with  strong
nitric acid, the  magnetizing  power  was  equal  to
96,000  grs.   The  mixture  of nitre  and  sulphuric
acid,  though  inferior to  strong nitric acid, makes a
good  exciting  solution.   Nitre, being  a nitrate  of
potash, is decomposed when added to sulphuric acid,
which forms  sulphate of potash and  liberates  nitric 
286           DAVIS'S  MANUAL.
acid.   Hence the active agent is here also nitric acid ;
but in using the mixture,  the disagreeable fumes of
nitrous acid produced by strong nitric acid alone are
in a great degree avoided.
   466.  Two of Grove's batteries, of the form repre-
sented in Fig. 178, were  connected with the mag-
netometer, at  first  united  as  a single pair and after-
wards consecutively, strong  nitric  acid being used
in the porous  cell.   The  following table gives the
magnetizing  power obtained : —

                    Table  IV.
      Battery No. 1,........80,000 grs.
         «   No. 2,........82,000  "
      Both, as  one pair,......88,000  "
        "   consecutively,.....97,000  "

   Owing to the magnetizing power being so great as
nearly to reach the  limit of  saturation of  the electro-
magnet, the numbers in this table do not indicate so
great an increase as really  occurs; but they show that
no great advantage is gained by connecting two pairs
as a single pair.   The  large-sized Smee's or Grove's
batteries  are  not much superior to the small ones.
Ten  pairs of  Smee's battery, connected as one, are
but'little better than one pair.
   467.  Separable Helices.—In  this  instrument,
 which is represented  in Fig.  179, there  are two
helices entirely separate from each other.   The inner
 one,  composed of  several  strands of insulated coarse
 copper wire, is fixed in a vertical  position on the base 
SEPARABLE  HELICES.        287
board.   One of its ends is connected with the screw-
cup A,  and the  other  with a  steel  rasp,  B.  The

                      Fig. 179.
exterior helix is of fine insulated wire, and can  be
lifted off  from the other,  which it  surrounds.  Its
ends are enclosed  in  two  brass  caps, to which the
extremities of the  wire  are soldered.   To these caps
are attached the screw-cups C and D.  A bundle of
annealed iron wires, of which the ends are seen in
the  cut, can be removed from  the inner helix when
desired.
  468.  In Fig. 180, the different parts of the instru-
ment are shown separately.   The exterior helix, a, is
removed from the  inner coil,  b, which is fixed to the
base board.   At c  is seen a brass tube, within which
48232353488923234853232323234823534853535323 
288            DAVIS'S  MANUAL.

is  the  bundle of iron wires, d, intended to be  intro-
duced  into the interior helix.  For giving the strong-

                      Fig-. 180.
   a--------a
est  shocks, the bundle should fill the hollow of the
helix.   The  other parts are lettered  in correspond-
ence with the last figure.
  469.  The bundle of iron wires being withdrawn,
let  a  wire connected with  one  pole  of a  galvanic
battery  be fixed in the cup A, and the other battery
wire be drawn over  the steel  rasp.    Bright sparks
will be seen, and if metallic handles connected with
C and D are  grasped  in the hands, as represented in
Fig. 179, slight shocks will be felt on completing the
circuit  at  the rasp,  and  stronger  ones when it is
broken,  as with  the  instrument described  in <§> 402,
which is on the same principle.
  470.  If a rod  of soft iron is introduced into the 
            SEPARABLE  HELICES.        289

helix, the spark is much increased, brilliant scintilla-
tions are produced, and the shock, when the circuit is
broken, becomes powerful.  The  iron  acquires and
loses  magnetism  whenever the  current begins  or
ceases  to flow, and induces secondary currents  in
both of the coils which surround  it.   In the coarse
wire coil,  which  conveys the  battery current, this
appears in  the  increased  sparks  and  scintillations.
In the  fine wire coil it is felt in the  strong shock
which results.
   471.  When the bundle  of iron wires is substituted
for the  soft iron rod, the spark and shock are much
greater.  If the rod or bundle of wires is introduced
gradually into the helix, the spark and shock increase
as it  enters.  The  intensity of the  shock  may  be
varied at pleasure,  by altering the  number of iron
wires,   the  addition of a single  wire  producing  a
manifest effect.  If a glass tube is slipped over the
iron wires  in the  helix,  it does not  interfere  with
their inductive action on the surrounding coils.  But
if a brass tube is passed over  them, their influence is
entirely suspended,  so far  as the shock and the spark
are concerned.  When the tube is  slipped partly over
them,  their influence is partially  suspended.   This
also is a means  of regulating the shock without alter-
ing the battery current.
   472.  The  neutralizing  action of the  tube is thus
explained.  The magnet induces in the  tube, as well
as in  the  two coils,  a secondary electric  current,
which  flows  around it when the circuit is completed
or broken.   This  secondary induces a tertiary cur-
               25 
290
DAVIS'S  MANUAL.
rent in  each of the coils, which flows at the first
instant  in  an opposite direction  to the  secondary
induced in  the  coil by the magnet,  and  therefore
retards it.   As the secondary current in the tube  is,
however, instantaneous, it induces another tertiary in
the same direction with itself when it ceases to flow.
The consequence is, that the quantity of the current
in either helix  is not  altered,  but its intensity is
reduced, owing  to the slowness of its  development.
This is always the effect of any closed  circuit in the
neighborhood  of an  inducing  magnet  or current,  on
other circuits  near it.
  473.  If the cups  of the fine  wire coil are joined
by  a  wire, it  will form a  closed circuit  around the
magnet, and will impair the spark when  the current
in the coarse  wire is interrupted, though not to  so
great an extent  as the brass  tube,  since the latter
offers a freer and shorter circuit  for the induced cur-
rent.  The spark is but slightly lessened when shocks
are taken from the fine wire coil, because the human
body  is too poor a conductor to allow of the ready
flow of  the  secondary through it.   A metallic cylin-
der surrounding  the helices will neutralize the sparks
and shocks as  completely as the enclosed tube.
  474.  When a bar of iron  is placed  within  the
helix, a secondary is induced in it in the same man-
ner as in the brass tube, which somewhat retards the
secondary currents in  the  coils.   Hence  the  greater
shock obtained  from a bundle of wires,  where this
secondary current cannot circulate.   To this cause is
added another — the  more sudden change in the mag- 
SEPARABLE  HELICES.         291
netism of the wires, when the battery current ceases,
from the  neutralizing influence of the similar poles
of the  wires on  each other.
  475.  If the secondary current can be hindered from
circulating in the brass tube, its retarding influence
will be prevented.  Thus, if the  tube  is longitudi-
nally divided on one side, it no longer diminishes the
shock  or  spark.   With the solid iron bar, the shock
and spark are  increased  by  sawing  it open  longi-
tudinally  to  the  centre.  A soft iron  tube, divided
like the brass tube, gives a stronger shock than the
bar, but is still  inferior to the bundle of wires.  The
two brass caps  at the ends of the fine wire coil would
exert a considerable  neutralizing  influence if they
were not  divided on  one side, as shown in  the  cut.
The ends of the  caps are  also cut  through  for the
same reason.
   476. In this instrument  there  are some  peculi-
arities in  the shock occasioned  by the motion of the
battery wire over  the  rasp.  If it is moved  slowly,
distinct  shocks  are  experienced;  if the  motion  is
quickened, the arms are  much convulsed; and  if it
is drawn  over  rapidly, the succession of  shocks be-
comes intolerably  painful.   This, however,  can be
easily  regulated.   The shock  from the secondary
coil increases  within  certain limits  in proportion  to
the length and  fineness  of the  wire  of which  it
is composed.   There  is  no  advantage obtained by
employing a  very long wire, unless the battery  is
powerful.  The  shock is also lessened if  a very fine
wire is used,  unless its length is moderate. 
292
DAVIS'S  MANUAL.
  477.  The strength  of the shock depends greatly
upon  the  extent  of  the  surface of contact between
the hands and the  metallic conductors.  Thus, if
two wires are fixed in the cups C and D, and grasped
in the hands, the  shocks will be slight in comparison
with those  given  by the  handles, and  still more so
if the wires are held lightly in the fingers.   These
effects, as well  as the  increase of the shock by wet-
ting  the hands, are due  to the comparatively low
intensity of the secondary  current,  which causes it
to be transmitted imperfectly by  poor conductors.
With frictional electricity it is  well known  that no
difference in the  shock is thus occasioned.
  478.  When the quantity  of the secondary current
is very small, an imperfect conductor, or a surface of
limited extent,  may  be able to convey the whole of
it, even if its intensity is not very  high;  in which
case,  the  sensation  and  muscular  contractions pro-
duced by it will not be increased, but  even lessened,
by any further increase  in the conducting  power.
Thus, if the shocks are received by placing the hands
in two vessels  of water connected with the  cups of
the outer helix, and the  current is rather feeble, it
will  produce the  strongest sensation when the ends
of the  fingers only are immersed.   With a powerful
current, the 6hock is intolerable, whether the surface
of contact with the  water is  large or small; in the
latter case, it extends to  a less distance up the arms,
though it may be felt very strongly in the fingers.
  479.  The shocks have sufficient  intensity to pass
without much  diminution through  a circuit  formed 
SEPARABLE  HELICES.         293
by several persons with their hands joined, especially
if their hands  are  moistened.   Different individuals
will  be found  to manifest remarkable  differences  in
regard to susceptibility  to  the shocks;  some being
but slightly affected, perhaps feeling  the shocks only
in the hands or arms; while others will feel them as
far as the  shoulders or across the  breast, and will
experience strong muscular contractions in  the arms.
   480. The difference in the strength of the shock
in the two arms,  which has  been  described  in  the
case of the  magneto-electric machine (see <§> 442,) is
exhibited more satisfactorily by the separable  helices,
as a  rapid succession of shocks may be  obtained  of
very  nearly the same intensity.  Suppose the  handle
connected with the positive cup of the exterior helix
to be held in the right hand, and the one connected
with the negative  cup  in the left  hand.  The  left
hand  and  arm will  then  experience  the strongest
sensations, and be  most convulsed.  In  determining
the positive or negative  character of the  cups, regard
should be had  only to the terminal secondary current,
it being found that the initial  secondary, whether in-
duced by means of a voltaic battery or a permanent
steel magnet,  produces comparatively feeble phys-
iological effects,  and consequently need not,  in this
case,  be taken into account.  This singular differ-
ence in the  intensity of the shocks  is regarded as a
purely physiological phenomenon, the greatest effect,
both as respects sensation  and muscular contractions,
being produced by the  electric current when it pro-
ceeds in the direction of  the ramification of the nerves.
               25 * 
294
DAVIS'S  MANUAL.
   481.  If the ends of the secondary  wire  are  put
into vessels of water, a peculiar shock may be taken
by putting the fingers or hands into the vessels, so
as to  make a communication between them through
the body.  If both wires are put into a trough, at
some distance  apart, and  two fingers of the operator
are placed in  the water in a line between the  two
wires, a  shock will  be felt.  Here the current  pre-
fers a passage  through the  body to that through  the
water which intervenes between  the  fingers.  The
conducting power of the water may be made better
than that of the human body  by the addition of a
sufficient  quantity  of common  salt; in which case,
little or no shock  can  be perceived.   If the fingers
are placed at  right angles  to the  line  between  the
wires, no  shock will  be felt.   The  trough should
not be  of metal,  but of  some  poor  conductor of
electricity.
   482.  If a delicate galvanometer is connected with
the ends  of the fine wire  coil, the needle  will be
deflected in opposite directions, and equally far, when
the battery circuit  is closed and opened.  The same
effect is produced when the brass tube is slipped over
the iron wires.  In this case, though the shock may
have been prevented, the induced current still passes.
The reduction in the intensity of the  current, while
its  quantity remains unaffected, depends  upon  the
same  cause as with the flat spirals, when a metal
plate  is interposed.  (See $ 421.)
   483.  When a flat coil of  fine wire, such as  that
represented at  W, in Fig. 167, is passed over the in- 
            SEPARABLE  HELICES.        295

terior helix (the exterior  one being removed),  the
shocks will be  found strongest  when  the coil sur-
rounds the middle of the helix,  and to decline con-
siderably in strength as it is either raised or depressed
from this position.   Now,  the magnetism  of the en-
closed  iron wires, which induces the principal part
of the  current, manifests itself chiefly at the ends of
the bundle; it might, therefore,  have been expected
that the  flat  coil would  give the strongest  shock
when surrounding one  of  these  ends.   The shocks
from the exterior helix are  also lessened when  it
is raised from the stand  so as to enclose only the
upper  part of the inner  helix.
   484.  Slight shocks may be obtained from the inner
helix itself, by connecting one of the handles with the
cup, A, and the  other with the rasp, B.   The bundle
of iron wires should be within the helix.  The shocks
are somewhat stronger when  one  handle  is in con-
nection with the rasp, and  the other with the battery
wire which is  drawn over it;  in this case, the battery
is included in  the circuit of the secondary current.
   485.  The  most important  principles  of magneto-
electric and  electro-dynamic  induction  are  conve-
niently illustrated by  the  separable  helices, in con-
sequence of the facility with  which  the powers  and
uses of  its several  parts  can be  exhibited.   The
observations which have been made with regard to
it apply equally well to the  following instrument,
which  is  a modified form.
   486.  Separable  Helices  and Electrotome.—
In the  instrument represented  in Fig. 181, the inner 
296
davis's  manual.
helix is connected with an electrotome, similar to that
described  in § 388, fixed on the same  base board, in
addition  to  the  steel rasp.  There are two cups, A
and  D, for the  battery wires; these are connected,
through the  electrotome, with the inner helix. When
the electrotome  is  set  in  motion, the curved  wire
dips its ends alternately into the glass cups contain-
ing  mercury, and rapidly  breaks the circuit.   One
end  of the coarse wire coil is  also connected  with
the steel  rasp, so that this may  be  used as in the
last-described  instrument,  when the current is not
made  to pass through the electrotome.    At  W is
seen the end of the bundle of wires, and  at T the
brass tube, which may be slipped over them  at pleasr
ure.   This  instrument, and others resembling  it in
beiug  provided  with a mechanical contrivance for 
    SEPARABLE HELICES & ELECTROTOME. 297

breaking  the  battery circuit,  may  be used  with a
very small battery, although its effects are of course
more striking with  a powerful one.
  487.  When the circuit is  broken at the  surface
of the mercury, an  intensely brilliant spark is  seen,
and the mercury is deflagrated, passing off in a white
vapor.   If the quantity of mercury is properly ad-
justed, the sparks  occur alternately in the two  cups,
and  in  such rapid succession  as  to  appear  simulta-
neous.  A little water or oil upon the surface of the
mercury diminishes  the brilliancy of the sparks, but
increases  the  intensity  of the  shocks.
  488.  These sparks are  of  so  short duration that
moving objects appear stationary by their light.  The
revolving armature (Fig. 142), although rotating many
hundred times a minute, appears at rest when viewed
in this  way; and where the sparks succeed  each
other rapidly, it appears to leap from place to  place
as their  light falls  on  it.  The revolving electro-
magnet  (Fig.  146), and other instruments which ex-
hibit  rapid  rotation, present  the  same  phenomena.
Many optical illusions of this kind may be observed,
as in moving the fingers rapidly,  when their number
seems increased,  or  rapidly turning over the leaves
of a  book,  when they seem  to  leap in  the  same
manner  as the armature.
  489.  If the ends  of the  secondary wire are sepa-
rated from each other at the same moment that the
battery  circuit is broken, a spark  will be seen  from
the  passage  of  the  induced  current.  A beautiful
light  is  produced if prepared  charcoal  points are 
298
DAVIS'S  MANUAL .
attached  to the  ends of the  secondary  wire  and
separated  in the  same way.
  490.  Water  may  be decomposed  by connecting
the ends of the fine  wire helix with an instrument
for  that purpose, having very small platinum wires
guarded with glass, as originally used by Wollaston.
These are prepared by inserting the wires into capil-
lary glass tubes, which are heated till the glass melts
and adheres to their  ends so as to cover them com-
pletely.  The  platinum points are then exposed by
grinding away  the glass.  It is of  course only neces-
sary to cover those parts of the wires intended to be
immersed in the fluid.
   491. The extremities of the platinum wires, while
the decomposition is going on, appear in a dark room,
one constantly and  brightly,  and the  other inter-
mittingly and feebly  luminous.   If the apparatus for
decomposition  is  removed  out of the noise of the
electrotome, rapid discharges are heard in  the water,
producing sharp, ticking sounds, audible at the  dis-
tance  of eighty or one hundred feet, and  occurring
at  the moments  when  the battery circuit  is broken.
Decomposition is effected both by the initial and ter-
minal secondary currents;  that is  to say, by the  cur-
rents induced both on completing and on interrupting
the battery circuit;  but the ticking noise and sparks,
accompanying the rapid discharges in the  water, are
produced only by the terminal  secondary current.
Both  gases, hydrogen and  oxygen, are given off  in
small  quantities  at each wire.  The  secondary cur-
rent  of the magneto-electric  machine  presents the
same  phenomena with the guarded points. 
   SEPARABLE HELICES  & ELECTROTOME. 299

  492.  A Leyden  jar, the knob of which  is  con-
nected with its inside  coating by a continuous wire,
may be feebly charged, and slight shocks be rapidly
received from  it,  by  bringing  the  knob in contact
with one of the cups of the outer helix, and grasping
with the two hands respectively the outer coating  of
the jar  and  a handle  connected with the other cup.
A gold leaf  electroscope is readily affected  by touch-
ing its  cap  with a wire  fixed in either cup  of the
exterior helix.  If the contact, which should be only
momentary, is made at the instant of the rupture  of
the primary circuit, the gold leaves exhibit  a con-
siderable divergence without the aid of a condenser.
Or  the  knob of a Leyden jar  may  be touched for
a moment with the wire, when  it will be found  to
retain a feeble  charge, capable of diverging the gold
leaves and of giving a slight shock.   The wire must
be well insulated from the hand  in which  it is held,
or the electricity  will be  conveyed  off.
  493.  If  the  large  thermo-electric battery  (Fig.
41) is  connected  with the cups A and D, and the
vibrating wire  put in motion,  faint sparks will  be
seen in  the mercury cups, attended by audible snaps.
Strong  shocks  may   be  obtained by  grasping the
handles attached to the fine wire coil, especially  if
both  heat  and cold are applied to the battery.  A
single thermo-electric pair, of antimony and bismuth,
or of German silver and brass, connected with A and
D,  will give  a slight shock  to the tongue  when
heated by a spirit lamp;  it will  be  more perceptible
when the ends of two wires fixed in  the  cups are 
300
D AVI S'S  MANUAL.
made  to  touch the tongue than  with a  more ex-
tended surface of contact.  This is probably due to
the small quantity of the  induced current.  These
sparks and shocks are, of course, not strictly thermo-
electric, but  magneto-electric.
  494.  When a bar of iron is contained within a
horizontal helix, such as is represented in Fig. 168,
where the circuit can be  rapidly broken, and a small
key or some  tacks are applied to one end of the bar,
they do not  cease  to  be sustained, notwithstanding
its magnetic  attraction  is intermitted every time the
voltaic circuit is interrupted, since it  is  almost in-
stantaneously renewed.   This  experiment succeeds
best when  the iron  bar is enclosed in a  brass tube
within the  helix,  the  closed   circuits of the  tube
tending to prolong its  magnetism.
  495.  If an iron tube of sufficient diameter to admit
a long helix of fine wire within  it is itself passed into
a coil of coarse wire, no shocks  can be obtained from
the enclosed  helix,  even when  the tube  is divided
longitudinally on one side,  to prevent the  flow of a
current in its substance which might neutralize that
of the fine wire.   This is  the  converse of the fact
stated in § 265, that a galvanic current passed through
a coarse wire helix, enclosed in  an iron tube, induces
no magnetism  in  the  tube.  Let one  or two iron
wires be placed  in  a glass tube contained within  a
tube   of iron, the  whole being surrounded by the
heliacal ring  described  in  <§» 273.   The  wires are
about as long as the tube,  and  their ends are made
to extend  a  little  beyond  one  of its extremities. 
            DOUBLE  HELIX,   &C         301

When  the helix is connected  with the  battery, po-
larity is induced  in the wires  in  the  same direction
as in the iron tube, and they are repelled until about
half of their length has passed out of the tube.  If
the circuit is broken at this instant, the momentum
which  they have  acquired causes them to be pro-
jected to some  distance.  In this  case, the  repulsion
overpowers the axial force, which tends to draw the
wires within the coil.   The action is strongest when
the helix surrounds that end of the tube from  which
they are projected.
  496.  Double  Helix  and  Vibrating Electro-
tome. — The instrument  represented  in Fig. 182  is
one of the most convenient for the medical applica-
tion of electricity.   It is  provided with  a self-acting
interruptor, by which shocks can be given with ex-
treme rapidity.  The double helix is secured to the
base board, in a  horizontal position, by two  brasa

                      Fig. 182.
bands.  The helices are  insulated from each  other,
but are not separable.    A bundle  of iron wires  is
shown in the cut, within  the inner  helix.   This can
              26 
302
D AVIS' S  MAN UAL.
be removed at pleasure.   The vibrating electrotome,
which is fixed on the stand, is of the same construc-
tion as that represented in Fig. 176, except that the
coil surrounding the electro-magnet,  M, is  shorter.
Near the electrotome are two screw-cups for battery
connections.  When the battery is applied, as shown
in the cut, the current traverses in succession the
coarse wire helix and  the  coil of the  electrotome.
The electro-magnet  is instantly charged, and attracts
its armature, causing the circuit to  be broken in the
manner described in <§> 456.   At the other extremity
of the base board are  the  screw-cups belonging to
the fine wire  helix.  With  these  the handles for
shocks are  connected.   With all the magneto-electric
instruments,  the battery connections must be made
by stout copper wires.  For attaching the handles to
the cups of the outer coil,  rather fine wire is  more
convenient.
  497.  With a battery of even moderate power, the
shocks  may be  made to  follow  each  other  with
exceeding rapidity.   When  their strength is lessened
considerably by removing nearly all  the  iron wires
from the helices, instead of distinct shocks, a peculiar
sensation of numbness is experienced,  extending a
greater or less distance up the arms, and attended by
loss of power over the muscles as far as it  reaches.
The shocks are  never so powerful with  a self-acting
interruptor  as when  the circuit  is broken mechani-
cally, since the battery current is obliged to maintain
the motion of the interruptor as well as to  traverse
a circuit of greater  length. 
SHOCKS   REGULATED.        303
  498.  There  is a steel  rasp above  the helices, by
means of which shocks are given without using the
electrotome.  For this purpose, the  battery wire is
removed from  one of  the  screw-cups  near M, and
drawn over the rasp.   It will be found  by trial from
which of the cups it is necessary to remove  the wire.
If the hollow of the  helix  is filled with iron wires,
bright sparks will be seen as the battery wire leaves
each tooth of the rasp, and  strong shocks will be felt
when one of the  handles is grasped in each hand.
When the  iron wires are withdrawn, the  spark be-
comes faint and  the  shock feeble.
  499.  The strength of the shock may be  regulated
by  varying  the  number of  iron wires  which  are
placed within  the  helix, or the distance  to which
the bundle is allowed to enter.   The addition  of a
single wire  produces  a perceptible increase  in  the
shock, especially when only a few are already within.
By wetting the hands or other parts to  which the
handles are  applied, especially  with  salt  water, the
shock is still stronger.   It  may, on the contrary, be
lessened in  some  degree  by diminishing  the extent
of contact between  the handles and the surface of
the body.   If,  however, the current is  powerful  and
the contact  too slight, a disagreeable  burning  sen-
sation will  be experienced at the part touched  by
the metal.
  500.  The shocks may  be passed through any por-
tion of  the  body,  by placing the handles so as to
include  that part  in  the  path of the secondary cur-
rent ; their  intensity  is greater when the handles are 
304
DAVIS'S  MANUAL.
near each  other.   The  influence does  not  extend
beyond the direct course of the current, unless the
shocks  are  severe.   When, however,  one  of the
handles is placed directly over a large and tolerably
superficial  nerve,  the  shock will be felt  not only
in the parts intervening between the handles, but
through  those  to which the  ramifications  of the
nerve are distributed.  Thus, if one handle  is held
in the right  hand,  and the  other  pressed  upon the
inside  of  the left arm over the median nerve, the
sensation will be experienced even to the  ends of the
fingers, attended  by convulsive movements of their
muscles.   This  is, unquestionably,  a physiological
phenomenon, and not a consequence of the flow of
the current  below the position of the handle.  The
difference in the intensity of the  shock  in the two
arms, described in § 480, may be observed with this
instrument.
  501. Compound Magnet  and Electrotome.—In
Fig. 183 a double helix is seen attached  to the base
board by two brass bands.  It is placed in a horizon-
tal position, and within it a  bundle of soft iron wires
is permanently fixed.   There are  two screw-cups for
the battery connections at one end of the stand; one
of these  is connected with the band which sustains
the glass  mercury cup, C.   To  the second screw-
cup is soldered one end of  the coarse wire coil, the
other extremity of which is connected with the band
upon which the brass cup, B, also intended  to hold
mercury, is fixed.  A bent wire,  W, moving on a
horizontal axis, dips its ends into the two mercury 
COMPOUND  magnet, & c.       305
cups.  On the opposite side of the axis is attached a
curved iron rod, R, the lower  extremity  of which

                      Pig. 183.
approaches nearly the end of the enclosed bundle of
iron  wires.
  502.  When  the  connections are made with the
battery, the current  traverses the wire,  W, and the
inner helix, causing the iron wires to become mag-
netic.   They now  attract the end of the iron rod,
R;   the  motion of the  rod  raises  the bent  wire
out  of  the  mercury in  the cup  C, and breaks the
circuit.   This  destroys the magnetism  of the iron
wires, and R is no  longer  attracted.   The wire, W,
then falls  back by  its own weight, and the circuit
is renewed.  A thin  slip of brass is brazed to  the
end  of  R, to prevent  it from being retained  by the
electro-magnet after the rupture of the circuit
  503  In this manner a rapid vibration of the wire
is nroduced, and brilliant sparks and deflagration  of
lheP mercur; take place in the cup C.  The proper
               26* 
306           davis's  MANUAL.

balance of  the  vibrating  apparatus is insured by
the brass ball, b, which moves on a screw cut  in  a
bent wire above the axis.   The ends of the fine wire
coil are connected with the two  screw-cups at the
opposite  end of  the  base  board  to  those  for  con-
nection with the  battery.   From  these  cups, the
shocks are  taken.
    III.  BY THE INFLUENCE OF  THE EARTH

   504. Currents of electricity  are  induced by ter-
restrial magnetism; but, in consequence of the feeble-
ness of the action, it is not easy to render it sensible
by the aid of wire  coils alone.   Deflections  may,
however,  be  obtained  by  connecting with a  very
delicate galvanometer a helix of coarse wire, such as
is represented in  Fig. 113, or a flat spiral, Fig. 112,
and, having placed its  axis in  the  line of the dip,
suddenly  inverting it.
   505.  Stronger  deflections are  produced by causing
a helix to revolve rapidly, as in the instrument rep-
resented in  Fig.  184.   The coil which  is  hollow,
moves in  a  vertical plane,  and  its  shaft is pro-
vided with a pole-changer, to the segments of which
the extremities of the wire are soldered.  The springs
pressing on these segments  convey the  currents to
the screw-cups on the base board.   When the cups
are connected  with those of a delicate galvanometer,
and the instrument placed  in such  a direction that
the helix  shall move in the magnetic  meridian, it is 
INDUCTION  BY THE  EARTH.     307
made to revolve rapidly by means of a multiplying
wheel.   As each  end of the helix approaches  and
recedes from the  line of the dip, opposite  currents
                     Fig. 184.
are induced  in the  wira,  their direction  changing
as the helix passes this point.
   506.  These  alternating  currents of electri.it/  are
turned into one course by the pole-changer, the seg-
ments of which may be so arranged as to pass from
one spring to  the  other when  the  helix is vertical,
this being sufficiently near the line of the dip, except
in low latitudes.   The galvanometer needle is stead-
ily deflected as  long as the motion is  maintained
uniformly.  By reversing the revolution of the helix,
a deflection in the  opposite direction takes place.
   507.  A  still more powerful effect is produced by
fixing an  iron bar  within the  hollow helix.   Let
the instrument  be now placed  in the plane of the mag-
netic  meridian, and the  cups connected with  a gal-
vanometer.   When the coil and  bar are made  to  re- 
308
DAVIS'S  MANUAL.
volve,  each end  of the iron becomes alternately  a
north and a south pole, the magnetism being induced
in it by the  earth, as explained in <§> 354.  By the
changes  in the magnetic state  of  the  iron, electric
currents are induced in the surrounding coil.  These
currents  change  their  direction twice during  each
revolution, but they are  brought into  one course by
the pole-changer  on the shaft of  the rotating coil,
and the needle of the galvanometer is strongly and
steadily deflected.   With this instrument, the current
is somewhat augmented  by the  feeble one excited in
the wire coil by the direct magneto-electric induction
of the earth.
   508.  In this, and in all other instances  where
electricity is  produced  by motion, and  motion re-
ciprocally by electricity,  the motion  must be the
reverse  of that which would result from  a galvanic
current flowing in  a certain direction, in order that
the induced  current may have the  same direction.
An opposite  current is  excited by  producing me-
chanically the same motion as that  obtained with
the battery. 
INDEX.
                                                        Sutton.
Amalgamated zinc,.......................................25
Ampere's electro-dynamic theory,...........................380
Analogy between magnetism and statical electricity,..........247
Animal electricity,........................................134
Arch of flame between charcoal points,.......................48
Armature,..................................................9
Artificial magnets,..........................................2
Attracting and repelling wires,..............................364
Attraction of armature,....................................228
------------currents, shown by frictional electricity,.........369
------------iron due to induced magnetism,................222
Attractions and repulsions, magnetic,........................140
________________________of magnets, cause of,..............383
Attractive force, instrument for measuring,...................237
--------------of bar magnets,........................243-246
_________________electro-magnet,..........................240
_________________long U-magnet,.........................239
_________________short U-magnet,.........................238
Astatic needle,...........................................15°
Aurora borealis affects magnetic needle,.....................219
Axial bell engine,.........................................28°
_____force,.  ............................................279
                                     .....................309
— magnetometer,........
— motion of bent iron bar,
                                 .........................289
                                                          321
Axial receiving magnet,.........................         • *
-----revolving bar,.......................................
_____________circle......................................2b7
                                                         . .323
----telegraph,........................                "\oa
______________with clock-work,...........................***
                                                          •JOK
______._____________engine,...............................°*° 
310
INDEX.
                                                         Section.
Bar magnet,................................................7
----------, attractive force of,.........................243-246
Batteries for electro-magnetic experiments,....................23
-------, power of,........................................461
-------, protected,......................................35-40
-------, sustaining,........................................40
Battery,  Grove's,..........................................41
--------Smee's,..........................................24
--------sulphate of copper,................................29
--------thermo-electric,..................................128
Blue vitriol, used in battery,.................................30

Calorimotor,...............................................21
Cell for delicate decompositions,.............................66
Clock-work electrotome,...................................388
Coil of fine wire, sparks and shocks from,...............397-400
Cold and heat produced by galvanism,.......................131
;----, instrument for showing the production of,..............132
Common salt used in battery,...............................35
Compass needle,..........................................207
Compound bar magnet,......................................7
---------magnet and electrotome,.........................501
---------U-magnet,.......................................8
Conducting power of metals,.............................55-58
Conduction of galvanism,...................................55
Constant batteries,.........................................40
Contracting helix,.........................................371
Copper deposited by the magneto-electric current,............448
Copperplates electrotyped,...............................78, 80
Copper solution for the electrotype,...........................88
Cylindrical sulphate of copper battery,........................29

De la Rive's  ring,.........................................] 85
Decomposing cell,..........................................64
Decomposition of water in Smee's battery,....................27
Decompositions in protected batteries,........................39
----------------sulphate of copper battery,.................31
Dip of magnetic needle,...................................210
Dipping needle,.......................................10, 208 
                           INDEX.                      311

                                                          Section.
Direction of poles, rule for finding,..........................257
Divergence of suspended iron wires,.........................225
Divided tumbler for decompositions,..........................67
Double axial bell engine,..................................290
------ beam axial engine,.................................293
------ cylinders of iron, with helix,........................274
------■ forceps for holding wires to be ignited,.................58
------ helix and electrotome,..............................402
------ helix and vibrating electrotome,.....................496
------ revolving magnet,..................................348
      ■ thermo-electric revolving arch,......................205

Earth, induction of electricity by the,.......................504
-----,----------magnetism by the,.......................353
-----, magnetic poles of the,...............................218
-----, magnetism of the,..............................215, 217
-----, used as  a conductor,................................318
Electric light, transient duration of,.....................182, 488
Electrical ray,............................................138
Electricity, animal,........................................134
---------, frictional,.......................................13
---------, from steam,.................................14, 15
---------, galvanic,.......................................1"
_________induced by the  earth,...........................504
---------■, induction of,......................................
_________instruments for showing  induction of, by the
               earth,.................................505,507
---------, magnetic,......................................4^"
---------, mechanical,.....................................1<J
---------, velocity of,....................................326
---------, voltaic,.........................................
           '                                             ......16
Electrodes,................................
Electro-dynamic revolving coil,.............................
___________.____________rectangle,........................«*7"
______________theory of Ampere,.........................380
Electro-dynamics,  phenomena of,...........................36<j
Electro-etching,.......•.................             " "gglj04
Electro-gilding and silvering,.....................
Electro-magnet,..................................... 
 312                      INDEX

                                                           Section
 Electro-magnet attracts through glass, &c,..................300
 --------------in case,...................................298
 --------------in frame,..................................296
 -------------, polarity of, reversed,........................297
 -------------, ------retained by,.........................296
 -------------, power of,..................................299
 --------------revolving by the earth's action,..........343, 345
 -----------------------on its axis,.......................351
 ------------------------within a coil,.....................347
 --------------with three poles,..........................301
 Electro-magnetic  induction,................................253
 ---------------telegraph,...........................310, 313
 Electro-magnetism,.......................................253
 -----------------as a motive power,......................352
 Electro-metallurgy,........................................71
 Electro-statics,...........................................360
 Electrotype,...............................................71
 ----------copies, bronzed, gilt, or silvered,..................93
 Elementary magnets,......................................249

 Fine wire coil,............................................397
 Fish-worm, galvanic experiments with the,....................53
 Flat spiral,...............................................275
 ---------, magnetism induced by,..........................277
 ---------, polarity of,.....................................276
 ---------, sparks and shocks from,.........................387
 Fracture of magnets,......................................247
 Frictional electricity,.......................................13
 ------------------, induced currents from,............424, 425
 ------------------, mutual attraction of currents shown by, . .369
 Frog used in galvanic experiments,..........................51
 Fusible metal moulds,......................................79

 Galvanic batteries,......................................24-49
 --------circuit,...........................................17
 --------current,.......................................16-18
---------------,  direction  of,...............................16
--------electricity,.......................................16
 -------series,...........................................21 
                           INDEX.                     313

                                                         Section.
Galvanism,................................................16
----------, conduction of,...................................55
----------, physiological effects of,...........................50
Galvano-decomposition,....................................62
Galvanometer,............................................158
------------deflected by secondary intensity current,.......482
----------------------------------quantity currents,.......394
------------, horizontal,..................................160
------------measures quantity,..........................163
------------, simple,.....................................158
---.---------, upright,....................................161
------------with astatic needle,..........................162
Gas-carbon,..............................................115
German silver,...........................................116
Gilding and silvering by the magneto-electric machine,.......450
-------by the galvanip battery,.............................98
-------------magneto-electric machine,....................449
-------, solution for,  ......................................102
-------without battery,...................................104
Glauber's suit used in battery,...............................35
Glycography,..............................................95
Gold leaf galvanoscope,...................................179
Grove's battery,...........................................^1
--------------,  construction of,............................44
--------------,  power of,.............................464-466
--------------,  series of,..................................45
Grasshopper's leg used in galvanic experiments,...............50
Gun-cotton used to show heating  of wire,.....................59
Gymnotus,...............................................136

Heat and cold produced by galvanism,.......................131
Heatine of wires shown by gun-cotton,.......................59
                                                            271
Heliacal ring,............................................**
___________, polarity of,..................................Zli
Helix,  action of,..........................................^3
-----,  iron bar sustained by,...............................^°
      '                                          ............278
-----,  magnetizing,..........................
              j                         ....................xo4
-----,  on  stand,.......................
27 
314                       INDEX.

                                                          Section
Horizontal galvanometer,..................................160
---------reciprocating engine,............................328
Horseshoe magnet,..........................................8
Hydrogen and oxygen obtained separately,....................65

Ignition of wire by galvanism,...........................56, 57
-----------------secondary current,......................460
Impressions of seals electrotyped,............................85
Improved magneto-electric machine,........................452
Inclined bar revolving round conductor,.....................285
-------revolving bar,....................................283
Induced currents from frictional electricity,..............424,  425
--------------,  table of,..................................423
Induction of a current on itself,........................384-392
-----------electricity,.....................................3
-----------magnetism,....................................3
----------------------not impeded by glass, &c,..........236
-----------secondary currents at a distance,................407
Initial and terminal secondaries,............................396
-----------------tertiaries,..............................420
-----secondary, intensity of,..............................399
Instrument for measuring attractive force,....................237
-------------showing revolution of mercury,...............377
Instruments for illustrating terrestrial  magnetism,........215,  217
Insulation of galvanic  electricity easy,........................22
Intensity and quantity,.....................................20
--------how increased,....................................21
--------of batteries compared,..........................42, 45
----------the thermo-electric current,......................125
Iodide of potassium decomposed by galvanism,................66
--------------------------------magneto-electricity,.......447
Iron, attraction of, by magnet,..............................222
----bar magnetized by the earth,...........................354
-------sustained within helix,.............................278
----filings around conducting wire,........................261
-----------------the poles of a magnet,...............145,  146
----increases sparks and shocks,......................470,  471
----wire in glass tube,....................................236
----wires superior to solid bar for sparks and shocks,........474 
                           INDEX.                      315

                                                          Section.
Leather partition used in battery,.........................37 3d
Leech, galvanic experiments with,.......................52, 53
Leyden jar charged by secondary current,...................492
Liebig's theory of muscular action,.........................1 ?,.">
Line of no variation,......................................211
Loadstone,.................................................2
--------, polarity of,......................................234

Magnet,...................................................2
Magnet and roller,...................................230, 231
------, attractive power of, long known,......................11
------ gains power when armature is kept on,...............252
------, iron tacks sustained by,  ............................233
------, polarity of, when discovered,.........................11
------ revolving on its axis,...............................167
-----------------round conductor,.........................166
Magnetic  attractions and repulsions,.........................140
--------curves,..........................................147
--------metals,............................................1
--------needle,...........................................10
---------------deflected by galvanism,....................149
---------------half brass,................................157
--------observations,....................................220
--------polarity, probable cause of,........................380
--------poles,..........................................4, 5
--------------of the earth,..........................215, 218
Magnetism and  statical electricity, analogy between,..........247
----------communicated by electro-magnets,...........302, 303
--------------------------percussion,....................356
---------------------------steel magnets,.................251
---------------------------twisting,......................357
---------, definition of term,................................1
------,----induced by secondary currents,..................395
__________________in iron by galvanism,...................254
----------, induction of,....................................3
__________,-----------, by the earth,......................354
----------of iron bar prolonged,...........................494
____________steel magnets, probable cause of,...............380
____________the earth, probable cause of,...................381 
316
INDEX.
                                                          Section.
Magnetism removed by electro-magnets,................304, 305
---------------------percussion,.........................359
Magnetizing helix,........................................278
-----------power of the magneto-electric current,...........451
Magneto-electric current, how excited,......................433
---------------------,  quantity and intensity of,............457
--------------currents,..................................440
--------------decompositions,............................446
Magneto-electric machine,................................ .437
-----------------------for quantity,......................458
-----------------------used with telegraph,...............306
-----------------------with vibrating electrotome,.........454
---------------shocks,...................................441
----------------------different in arms,...................442
----------------------varied,............................443
---------------sparks,..............................444, 453
----------------------from coarse wire helix,..............487
---------------------------fine wire helix,................489
Magneto-electricity,.......................................426
Magnetometer,...........................................307
Magnets, attractive force of,...............................237
--------charged,........................................251
-----------------by the electro-magnet,...................302
--------discharged,.................................304, 305
-------------------by percussion,........................359
Mechanical electricity,.....................................13
----------power from electro-magnetism,..................352
Medals electrotyped,....................................79, 80
Medical  use,  magneto-electric apparatus for,.................496
Melloni's thermo-multiplier,................................130
Mercury, revolution of,....................................377
Metallic  chromes,.........................................105
Metals, conducting power of,................................58
------ deposited by galvanism,..............................72
------------------the  magneto-electric current,........448-450
Muriate  of ammonia decomposed,............................69

Natural  magnets,...........................................2
Needle,  astatic,...........................................156 
                           INDEX.                      317

                                                          Section.
Needle, dipping,......................................10, 208
-----, horizontal magnetic,...............................207
-----, magnetic,..........................................10
Nitre, use of, in Grove's battery,.......................464, 465
Nitric acid, used in Grove's battery,.....................42, 465

One metal, galvanic current from,...........................19
--------, thermo-electric current from,....................108
Optical illusions in  electric light,.......................182, 488
Oxygen and  hydrogen obtained from water,..............64, 445
--------------------------separately,...................65

Percussion, induction of magnetism by,.....................356
--------, magnetism removed by..........................359
Permanent magnets,........................................6
Physiological effects of galvanism,...........................50
-----------phenomena of shock,.....................480, 500
Plaster casts electrotyped,...................................83
Platinum deposited by galvanic current,......................97
-------employed in Smee's and Grove's batteries,.......24, 41
-------solution of, for platinizing,..........................97
-------wire ignited by galvanism,.........................57
--------------------secondary current,.................460
Polarity of magnet, when discovered,.........................11
Pole-changer,............................................191
Poles, a little within ends of magnet,........................230
----, magnetic, of the earth,..........................215, 218
-----  of galvanic battery,...................................16
-------magnet, ........................................4, 5
Porous cell used in Grove's battery,......................44, 99
-----------------protected batteries,...................35-38
Powder cup,..............................................59
Protected batteries,......................................35-40
Primary magneto-electric current, effects of,.............445-451
___________________________, quantity and intensity of,... .457

Quantity and intensity  of galvanic electricity,.................20
____________________magneto-electric current,............457
._______.____________thermo-electric current,.........124, 125
                  27* 
318                      INDEX.

                                                         Section.
Quantity, how increased,...................................21
------measured by galvanometer,.........................163

Receiving magnet,........................................320
Reciprocating armature engine,.............................327
-----------coil engine,.................................189
-----------magnet engine,..............................190
Registering revolving magnet,.............................342
Removal of magnetism by the electro-magnet,...........304, 305
---------------------percussion,.......................359
Repulsion of iron wires,...................................226
-------------------from iron tube,.....................495
Revolving armature,......................................329
----------------engine,...............................331
--------bell engine,....................................340
--------coil,...........................................191
------------and  magnet,................................195
--------cylinder,.......................................170
--------disc,........................................... 184
--------electro-magnet,.................................336
--------galvanometer needle,............................194
--------rectangle,......................................193
--------spur-wheel,....................................180
--------wheels,........................................350
---------------with electro-magnet,.....................349
--------wire frame,.....................................168
Ribbon spiral,............................................275
-----------, magnetizing power of,........................277
-----------, polaritj' of,..................................276
-----------, sparks and shocks from,..................387, 390
Ritchie's revolving  magnet,................................ 338
Rolling armature,.........................................229
Rotating battery,..........................................173
Rule for  finding  direction of poles,..........................257
-----------------------polarity induced by helix,.........264

Seals electrotyped,.........................................85
Secondary current,...................................392, 396
---------------,  gold leaf electroscope deflected by,........492 
                           INDEX.                      319

                                                          Section.
Secondary current, in helices enclosing iron,.................459
------------------Leyden jar charged by,..................492
----------------,  sparks from,............................489
----------------,  water decomposed by,....................490
-----------------,  wire ignited by,.........................460
---------currents, from frictional electricity,................424
------------------, galvanometer deflected by,...............394
-------------------induced by intensity current,............405
-----------------, magnetism induced by,..................395
-------------------obtained by moving battery plate,........412
-------------------------------------coils,...............413
------------------separated from the primary,..............393
Sensation occasioned by two metals in mouth,.................54
Separable helices,.........................................467
-----------------and electrotome,..........................486
Shock depends on surface of contact,........................477
------from fine wire coil,.................................398
-----------galvanic battery,..............................406
-----------initial secondary,..............................399
-----------interior helix,.................................484
Shocks and sparks  from double helix,.......................403
----------------------long wire,......................384-386
----------------------ribbon spiral,.......................387
----------------------separable helices, — ,...............469
______________________thermo-electric battery,..............493
-----------------,  neutralization  of,...................409, 471
__________________________________prevented,.........411, 475
------------------increased by a bar of iron,................470
_______________________________bundle of wires,.......471, 474
Shocks, difference of, in arms,..............................480
-------differences in,.....................................476
-------from double helix and vibrating electrotome,..........497
------------feeble current,...............................478
------------fine wire coil varied,..........................408
_______-----flat coil surrounding helix,.....................483
______------magneto-electric machine,.....................441
____________primary magneto-electric current,..............444
______  given to several persons at once,.....................479
____.—  passed  near a large nerve,...........................500 
320                       INDEX.

                                                          Section.
Shocks passed through any part of the body,.................500
------ regulated,....................................443, 499
Signal key,..............................................317
Silurus electricus,.........................................139
Silvering by the galvanic battery,........................98-103
--------, solution for,....................................101
---------without battery,.................................104
Simple galvanometer,.....................................158
Single beam axial engine,..................................294
Smee's battery,........................................24, 89
-------------, power of,..................................461
Sources of magnetism,.....................................250
Sparks, extremely short duration of,....................182, 488
-------from secondary current,............................489
------------magneto-electric machine,.....................453
-------taken from mercury,...............................487
Star plate,................................................223
Steam, electricity from,.....................................14
Steel  magnet, iron sustained by,............................233
----  magnets charged,................................251, 302
------------discharged,.............................304, 359
----  plates electrotyped,....................................78
----  used for magnets,......................................6
----  wire ignited,.........................................57
Successive induction of magnetism,.........................232
Sulphate of copper batteries,.............................29-40
-----------------decomposed by magneto-electricity,.......448
----------soda decomposed by galvanism,...................68
--------------used in battery,.............................35
Sulphuric acid used in batteries,.........................25, 46
--------------------Grove's battery,...................35, 42
Sustaining batteries,.......................................40

Tangential action of current,..........................152, 382
---------forces cause attraction  and repulsion,.............258
Telegraph, axial,..........................................323
---------, battery for operating,............................316
---------, electro-magnetic,...........................310, 313
---------, migneto-electric machine  used with,..............316 
                          INDEX.                      321

                                                         Section.
Telegraph, with clock-work,...............................315
Telegraphic alphabet,.....................................314
-----■----  writing,......................................316
Terminal secondary current compared with initial,............399
Terrestrial magnetism, instruments to illustrate,.........215,  217
------------------,  probable cause of,....................381
Tertiary currents,.........................................416
---------------from wire  coils,.......................... 419
Thermo-electric arch between poles of U-magnet,............202
-------------battery,...................................128
--------------------, sparks and shocks from,.............493
-------------combinations, table of,......................117
-------------current, cause of,...........................109
--------------------, direction of,........................112
--------------------from a single metal,................108
--------------------reversed,..........................120
-------------pairs,.....................................117
-------------revolving arch,............................196
--------------------------on U-magnet,................199
----------------------wire frames,......................201
-------------series,....................................127
Thermo-electricity,........................................106
---------------, quantity and intensity of,................124
Thermo-multiplier,........................................130
Torpedo,.................................................I38
Trough batteries,.......................................46-49

U-magnet,.................................................8
U-tube, for decompositions,..................................70
Upright axial engine,......................................291
-------galvanometer,.....................................1"!

Variation of magnetic needle,..............................."14
___________.-----, how found,...........................216
Velocity of electricity,.....................................326
Vibrating armature engine,............................334» 335
-------coil engine,.....................................I"7
_-------electrotome,......................»..............455
-------helix,...........................................288 
322                      INDEX

                                                           Section.
Vibrating wire,......................................175, 177
Voltaic electricity,.........................................16
------  gas pistol,..........................................60
Voltameter,...............................................65

Water decomposed by galvanism,............................63
--------------------magneto-electricity,..................445
--------------------secondary currents,...................490
-----------------in Smee's battery,........................27
Wax moulds,..........................................80,  83
Wire conveying current does not attract light bodies,.........362
---- ignited by  current,....................................56
Wires of electro-magnetic telegraph,........................319
-----for conveying electric currents,...................55, 496
Woodcuts electrotyped,.....................................80

Y-armature,..............................................227

Zinc plates amalgamated,...................................25 
 
 
 
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