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/^'chael Faraday; his life and work.
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THE CENTURY SCII'JNCE SICRIES
Edited BY SIR HENRY E. ROSCOE, D.C.L., LL D.. F.R.8.
MICHAEL FARADAY
HIS LIFE AND WORK
The Century Science Series.
Edited hy Sir HENRY ROSCOE, D.C.L., F.R.S.
y?.. 6cl. each.
Pasteur.
Hv Prrcy FRANk-|,A\-D, Ph. D.( W ii rzburg) , r..Sc.(T.ond. ),
!■■. 1\.S,, :iiid Mrs. Pkncv FkanivI.and.
Humphry Davy, Poet and Philosopher.
IJy \. E. Thokif, i.L.l)., F.R.S.
Charles Darwin and the Theory of Natural
Selection.
Ily ttiWAKii B. PoitLTON', M.A., F.R.S.
John Dalton and the Rise of Modem Chemistry.
lly Sir HexKV R. Ri iscok, V R. S.
Major Rennell, F.R.S., and the Rise of English
Geography.
F>y Sir Ci.emknts R. Markham, C B., F.R.S.
Justus von Liebig : his Life and Work (1803-1873).
Bv W. A. Shi:nst'im.:, F.FC, Lei:tiirer on Chemistry in
Clirti>n College.
The Herschels and Modern Astronomy.
Bj AciNES RI. Cl.KK'KI^.
Charles Lyell and Modem Geology.
By Professor T. G. Bonnev, F.R.S.
J. Clerk Maxwell and Modern Physics.
i)y K. T. Glazkuroi^ic, F.R.S.
Michael Faraday : his Life and Work.
By Prof. Sii-\-ANus P. Thomi'son, F.R.S. 5s.
CASSELL .*v COMPANY, Limited, London, Paris, Nciu
\'ork &^ Melbonriie.
THE CENTURY SUIENUE SERIEH
MICHAEL FARADAY
HIS LIFE AND WORK
IIY
SILVANUS i\ THOMPSON, D.Sc, F.E.S.
I'lUM'lI'AL OF AND PROl'K.SS. H; uV PltYSiry, [-_: TlLi: ClTV AND GULLLS
01' LO.NDOX Tei.'UNH.'AL C'0LLE(.;E, r'iNSDI.'l;V
CvVSSELL AXD COMPANY, Limited
LOiVnON, PARIS, XRW YORK ,y- MRLBOURNE
18! IS
[all riohts rf.sf.rved]
ON A ruliTKAlT OF FARADAY.
AVas ever man so ainijjle and so sage,
So crowned and yet no careleys of a prize !
Groat Faraday, who made the wurld so wise,
And loved the lahouv better than the wage.
And this j'ou say is how ho looked in age,
AVith that strong Lrow and these groat humLlo eyes
That seem to look with reverent surprise
On all outside himself. Turn o'er the page,
Recording Angel, it is white as snow.
Ah God, a fitting messenger was he
To show Thy mysteries to us below.
Ohild as he came has he returned to Thee.
Would he could come but once again to show
The wonder-deep of his siinpiicity.
Cosmo AIoxkhouse.
PREFACE
Sm.'RTLY after the deatli of Farada}' in 1^G7. three
biograjjhit'S of hiiu—eaeh admirable in its own Hne —
were piildished. Tlie " Life and Letters of Faraday/'
by 1 'r. Eence Jones, secrt-tar}" ot the Er-yal Institiui<jn,
"which was issued in LSO^ in two vohunes. has lonu'
been out C'f print. ■■ Faradav as a I'lscoverer." written
in L^i.ls l.y- Prr)fessor Tvndall, which, though shghter
as a record, brings otit many points of character into
striking rehef. is alsr. now exhausted. I»r. (.Thidstone's
'■ Michael Faraday."" pul-li^hed in 1^72. so rit-h in
reminiscences, and so appreciative of the moral and
religious side of his character, is also out oi print.
Other and briefer bi<.'graphie>' exist : the "■ Floge
Historique " of M. Dumas: the article •■ Faraday '" in
the ■" Fncyclopa:-dia Britannica "' by Professor (.lerk
!^Lxxwell : and the chapter on Faraday in 1 'r. W.
Garnett's '■ Heroes of Science." But there seenis
r'jom t'nY another account of the life and lab'.'urs of
the man whose influence upon tlie century in wliich
Vlll MICHAEL FARADAY.
ho lived was so great. For forty years lie was a
livint;- and inspiring voice in the PLoyal Institution,
beyond all question the greatest scientific expositor
of his time. Throughout almost the whole ot that
time his original researches in physics, and chicHy
in electricitv, were extending the boundaries of knoAv-
ledge and laying the foundations not *»nly for the
great developments of electrical engineering of the
last twenty years but for those still greater develop-
ments in the theories of electricity, magnetism, and
light which are every year being extended and made
fruitful. Were there no other reason than these
developments in practice and theory, they would
amply justify the effort to review now, after so many
years, the position of Faraday amongst the eminent
men of the century now drawing to its close.
Those who were intimately acquainted with him
are a fast dwindling band. In the recollection of
such as have survived him, his image lives and
moves, surrounded with gracious memories, a vivid
personality instinct with rare and unseltish kindliness.
But the survivors are few, and their ranks orosy
thinner with each succeeding year. And so it comes
about that the task of writing of his life and worlv
has been entrusted to one who never ceases to re^q-ct
that he never met Faraday.
PREFACE. IX
Thanks tu tlio pennissioii of the managers of the
Koyal Institution, a number of short extracts from
Fara(Ia3^'s notebooks, hitherto unpubhshed, are now
printed for the first time. Mucli more remains which
it is to l.)C hoped, for the benefit of science, may be
published ere long. The author desires further to
acknowledo^e the kindness of Messrs. Loni-^mans & Co.
in allowing the reproduction of the illustrations on
pages o and 258, whicli are taken from Bence Jones's
"Life and Letters of Faraday," published in ISOS.
Mr. Elkin Mathews has kindly permitted the inser-
tion of the sonnet by Mr. Cosmo Monkhouse which
follows the title-page. The author is also indebted
to Dr. J. Hall Gladstone, F.R.S., for many valualjle
notes and suggestions, and to Miss M. K. Reynolds
for photographs used in preparing Fig. 14. Most of
all he is indebted to Miss Jane Barnard for access
to Faraday's private papers, and for permission to
print certain extracts from them.
S, R T.
CONTENTS
PAGE
Chap. T. — Evht,v Life. Tkaixino. and Travel ... 1
Chap. II. — Life at the Koyai. Ixstitution . . , .00
Chat. III. — ISciextific Keseaucties — First Pekiuu . To
Chap. IA^. — Scientific Keseakche.s — Secund Pehiud . 1U2
Chap. A". — Si/ientific ^iE^EARcnEs — Thihd Peiuoj) . . 172
Chap. VI. — AIiddle and Later Life ..... 'J22
Chap. A'IL— A'iews ox the Pii;suit of Sltlxce axd ox
Educatiox ....... 2G1
Chap. A'III. — Keligiuvp A^iEWb ...... 2SG
LIST OF ILLUSTRATIONS
Portrait
FIGS.
1
Riebau's Shop .......
2. Electronifignetic Uutatioii-s (facsimile sketch
3. Apparatus for Rotation (facsimile skoti-h)
4. Faraday's Ring {facsimile sketch)
5. Induction Experiment {facsimile sk-etch)
G. The '^ Xow Electrical Machine " (facsimile sketch)
7. The Teetotum Apparatus .....
IS. The Revolving- Copper Cylinder (facsimile sketch)
9. Earth Inductor .......
10, A Spark from a Magnet (t';icsimile sketch)
11. Ildw to Cut the IMagnetio Lines
Illustration of the New Ti'rms (facsimile sketch)
Bundle of AVires (facsimile sketch)
A})p;u-atus for Investigating Dielectric Cup.icity
Block of Heavy-glass (facsimile sketch)
IG. Action of Miignet on Light (facsimile sketch)
IT. AtTimgemi.'nts of Miignuts (facsimile sketch)
18. The Ring Electromagnet (facsimile sk.etch)
19. The Equatorial Position ....
20. Illustratiun of Lateral Vibrations
21. A Lecture Model . , , . .
22. Cottage at Hampton Court
PAGE
3
88
88
108
111
121
123
124
12o
129
133
145
l.')!
159
17G
177
178
179
188
195
239
258
MICHAEL FARADAY.
CHAPTER I.
EARLY LIFE, TRAINING, AND TRAVEL.
On the 22nd of September, 1791, was born, at
Newington Butts, then an outlying Surrey village,
but since long surrounded and swallowed up within
the area of Greater London, the boy Michael Faraday.
He was the third child of his parents, James and
Margaret Faraday, who had but recently migrated
to London from the little Yorkshire village of
Clapham. Clapham lies under the shadow of Ingle-
borough, on the western border of the county,
midway between Settle and Kirkby Lonsdale. The
father, James Faraday, was a working blacksmith ;
the mother, daughter of a farmer of Mallerstang, the
romantic valley which runs past Pendragon Castle to
Kirkby Stephen. James Faraday Avas one of the ten
children of a Robert Faraday, who in 1756 had
married EHzabeth Dean, the owner of a small home-
stead known as Claphum Wood Hall, since pulled
down. All Robert Faraday's sons appear to have
been brought up to trades, one being a -shoemaker,
R
2 MICHAEL FARADAY.
another a q-rocer, another a farmer, another a nax-
workcr, and another a shopkeeper. Descendants ot
some of these still hve in the district.
After Michael's birth, his parents moved to the
north side of the Thames, living for a short time
in Gilbert Street, but removing in 179G to rooms
over a coach-house in Jacob's Well Mews, Charles
Street, ]\Ianchester Square, Avhere the}^ lived till
1809. In that year, young Michael being now nearly
eighteen years old, they moved to IS, Weymouth
Street, Portland Place. Here in the succeeding
year James Faraday, who had long been an in-
valid, died ; his widow, who for some years re-
mamed on at Weymouth Street, maintaining herself
by taking in lodgers until her sons could support
themselves and her, survived till 1838. Though a
capable woman and a good mother, she was quite
uneducated. In her declining years she was wholly
supported by her son, of whom she was very proud,
and to whom she was devoted.
Michael received very little schooling. One of
his nephews tells the following tale of his boy-
hood. He was at a dame's school ; and, either from
some defect in his speech or because he was too
young to articulate his r's properly, he pronounced
his eider brother's name " Wobert." The harsh
schoolmistress, bent on curing the defect by personal
chastisement, sent the aforesaid " Wobert " out with a
halfpenny to get a cane, that young Michael might be
dul}^ flogged. But this refinement of cruelty reacted
on itself; for Robert, boiling with indignation, pitched
the halfpenny over a wall, and went home to tell his
BOOKP.INDEirs EKRAND-BOV.
3
mother, who promptly came down to the scene of
action and removed both boys from the school.
From the age of five to thirteen Michael lived at
Jacob's Well Mews, spending his out-of-school hours
ll
Jil
iA
,llllll
I'li;
'iiill
'i h
1 M
i
I
U II ^
—^
1 ' 1 i| "1
KIEJiAU S SHUP.
at home or in the streets playing at marbles and
other games with the children of the neighbourhood.
In 1804 he went on trial for twelve months as
errand-boy to a bookseller and stationer at No. 2,
Blandford Street — Mr. George Riebau. This
house, which is still kept as a stationer's shop
(by Mr. William Pike), is now marked with an
enamelled . tablet recording its connection with the
4 MICHAEL FARADAY.
life of Faraday.-^ When he first went to Mr. Riebaii,
it was his duty to carry round the newspapers
in the morning. He has been graphically described
as a bright-eyed errand-boy who " slid along the
London pavements, with a load of brown curls upon
his head and a packet of newspapers under his arm."
Some of the journals were lent out, and had to be
called for again. He Avas very particular on Sunday
mornings to take them round early, that he might
complete his work in time to go with his parents
to their place of Avorship. They belonged — as his
grandfather before him — to the sect known as Sande-
o
manians, a small body Avhich separated from the
Presbyterian Church of Scotland towards the middle
of the eighteenth century. Their views, which were
very primitive, were held Avith intense earnestness
and sincerity of purpose. Their founder had taught
that Christianity never was or could be the formal or
established religion of any nation Avithout subvertmg
its essential principles ; that religion Avas the affair
of the individual soul; and that "the Bible" alone,
Avith nothing added to it or taken aAvay from it by
man, Avas the sole and sufficient guide for the soul.
They rejected all priests or paid mmisters, but
recognised an institution of unpaid eldership. Their
Avorship Avas exceedingly simple. Though their
numbers Avere fcAV, they Avere exceedingly devout,
simple, and exclusive in their faith. Doubtless the
rigorous moral influences pervading the family and
^' Faraday's usual place of work at bookbinding was a little room
on the left of the entrance. [See the story of his visit there with
Tyndall in after years, as narrated in Tyndall'a " Faraday," p. 8.)
APPRENTICED AS BOOKBINDER. 5
friends of James Faraday had a great part in
moulding the character of young Michael. To his
dying day he remained a member of this obscure
sect. As he was no merely nominal adherent,
but an exceedingly devoted member, and at two
different periods of his life an elder and a preacher,
no review of his life-work woidd be complete with-
out a fuller reference to the religious side of his
character.
After the year of trial, Michael Faraday was
formally apprenticed to learn the arts of bookbinder,
stationer, " and bookseller," to Mr. Riebau. The in-
denture* is dated October 7, 1805. It is stated that,
" in consideration of his faithful service, no premium
is given." During his seven years of apprenticeship
there came unexpected opportunities for self-improve-
ment. Faraday's lifelong friend and co-religionist,
Cornelius A'^arley, says : — " When my attention was
first drawn to Faraday, I was told that he had been
apprenticed to a bookbinder. I said he was the best
bookworm for eating his way to the inside ; for
hundreds had worked at books only as so much
printed paper. Faraday saw a mine of knowledge,
and resolved to explore it." To one of his friends he
said that a book by Watts, '■' On the Mind," first made
him think, and that the article on " Electricity " in a
cyclopaedia which came into his hands to be bound
first turned his attention to science. He himself
wrote : — '' Whilst an apprentice I loved to read the
scientific books which were under my hand ; and,
^ Still preserved in Faraday's Diploma-book, now in the possession
of the Royal Society.
6 MICHAEL FARADAY.
amoncrst them, delis-^btecl iii Marcet's 'Conversations
in Chemistry' and the electrical treatises in the
' Encyclopaedia Britannica.' I made such simple
experiments in chemistry as could he detrayed m
their expense by a fe^v pence per Aveek. and also
constructed an electrical machine, tirst ^vith a c^lass
pliial, and afterwards with a real cylinder, as well a.s
other electrical app>aratus of a corresponding kind."
This early machine * is now preserved at the Eoyal
Institution, to -which it was presented Ly Sir
.Tames South. Amono-st the books which he had
ti) bind were Lvons' "Experiments on Electricity"
and Boyle's " Notes about the Producibleness of
Chymicall Principles/' which books, together
with Miss pjurnev's " Evelina," all boimd with his
own hands, are still preserved in the Roval Insti-
tution.
AValking ]iear Eleet Street, he saw displayed a bill
announcing that evening lectures on natural phil-
osophy were delivered by Mr. Tatum at 53, Dorset
Street, Salisbury Square, E.C., price of admission one
shilling. With his master's permission, and monev
furnished by his elder brother Robert, who was a
blacksmith and (later) a gastitter, Michael bec^an
to taste scientitic teaching. Between Eebruarv,
ISIO, and September, IMl, he attended some twelve
or thirteen lectures. He made full and beautiful
notes of all he heard : his notebooks, bound bv him-
self, being still preserved. At these lectures he fell
in with several thoroughly congenial comrades, one
An account of this machine will be found in the Argonaut
vul. ii., p. 33.
NEW ACQUAIXTAXCES. /
of theiH, by name Uenjamin Abbott, being a well-
edncated young Quaker, who was contidential clerk
in a mercantile house in the City. Of the others —
amongst whom were IMagrath, Newton, Nicol, Hux-
table, and Richard PhiUips (afterwards F.R.S. and
President of the Chemical Society) — several remained
lifelong friends. Happily for posterit}^ the letters —
long and chatty — Avhich the lad wrote in the fulness
of his heart to Abbott have been preserved ; they
are published in IJence Jones's "Life and Letters."
They are remarkable not only for their vivacity
and freshness but for their elevated tone and ex-
cellent composition — true specimens of the lost art
of letter-writing. The most wonderful thing about
them is that they should have been Avritten by a
bookbinder's ajiprenticc of no education beyond the
common school of the district. In his very lirst
letter he complains that ideas and notions which
spring u]) in his mind "are irrevocably lost for w^ant
of noting at the time." This seems the first premoni-
tittn of that loss of memory wdiich so afflicted him
in after life. Tn his later years he always carried
in his waistcoat pocket a card on which to jot down
notes and memoranda. He would stop to set down
his notes in the street, in the theatre, or in the
laboratory.
Riebau, his master in the bookbinding business,
seems, from the way he encouraged the studies of his
young apprentice, to have been no ordinary man.
His name would suggest a foreign extraction ; and
to his shop resorted more than one political refugee.
There lodged at one time at Riebau's an artist named
S MICHAEL FARADAY.
Masquerier,* who had painted Xapoleous portrait
and had tied from France during the troublous times.
For the apprentice boy, who used to dust his room and
black his boots, Masquerier took a strong liking. He
lent him books on perspective and taught him hou'
to draw. Another frequenter of Riebau's shop was
a Mr. Dance, whose interest in the industry and in-
telligence of the apprentice led him to an act which
changed the Avhole destiny of his life. Faraday
himself, in the very few autobiographical notes which
he penned, wrote thus : —
During my apprenticeship I had the good fortune, through
the kindness of Mr. Dance, who was a customer of my master's
shop and also a member of the Eoyal Institution, to hear four
of the last lectures of Sir H. Davy in that locality.t The
dates of these lectures were February 29, March 14, April 8
and 10, 1S12. Of these I made notes, and then wrote out the
lectures in a fuller form, interspersing them with such draw-
ings as 1 could make. The desire to be engaged in scientific
occupation, even though of the lowest kind, induced me,
whilst an apprentice, to write, in my ignorance of the world
and simplicity of my mind, to Sir Joseph Banks, then President
of the Royal Society. Naturally enough, " Xo answer" was
the reply left with the porter.
He submitted his notes to the criticism of his
friend Abbott, with whom he discussed chemical and
electrical problems, and the experiments which they
had individually tried. Out of this; correspondence,
"■ " When he [Famday] was young, poor, and altogether unkno\^-n
ilasquerier was kind to him; and now that he is a great man he
does not forget his old friend." — Diary of H. C'rahh Eobinson, vol. iii
p. 375.
t He alwavs sat in the o-allerv over the clock.
LET'I'ERS TO ABliOTT. \)
one letter only can be given ; it Avas written Sep-
tember 28, 1812, ten days before the expiry of his
apprenticeship : —
Dear A , . . . T will hurry on to philosophy, where I
am a little more sure of my grouod. Your card was to me a
very interesting' and pleasing ol'ject. I was highly gratified in
observing so plainly delineated the course of the electric fluid
or fluids (I do not know which). It appears to me that by
making use of a card thus prepared, you have hit upon a happy
illustrating medium between a conductor and a non-conductor ;
had the interposed medium been a conductor, the electricity
would have passed in connection through it — it would not have
been divided ; had the medium been a non-conductor, it would
have passed in connection, and undivided, as a spark over it,
but by this varying and disjoined conductor it has been divided
most efi"ectually. iShould you pursue this point at any time
still further, it will be necessary to ascertain by what particular
power or eflbrt the spark is divided, whether by its aflinity to
the conductor or by its own repulsion ; or if, as I have no
doubt is the case, by the joint action of these two forces, it
would be well to observe and ascertain the proportion of each
in the effect. There are problems, the solution of which will
be diflicult to obtain, but the science of electricity will not he
complete without them ; and a philosopher will aim at perfec-
tion, though he may not hit it— difficulties will not retard him,
but only cause a proportionate exertion of his mental faculties.
I had a very pleasing view of the planet Saturn last week
through a refractor with a power of ninety. I saw his ring
very distinctly ; 'tis a singular appendage to a planet, to a
revolving globe, and I should think caused some peculiar
phenomena to the planet within it. I allude to their mutual
action with respect to meteorology and perhaps electricity. . . .
The master, a French emigre named De la Roche,
of King Street, Portman Square, to whom he en-
gaged himself as a journeyman bookbinder, was of a
10 MiCtlAEL FARADAY.
very passionate disposition, and made Faraday very
luiconifortable. He long-ed to tret out of trade, and
under the enconragenient of Mr. Dance he wrote to
Sir Humphry Davy, sendino", " as a proof of my
earnestness,*' the notes he had taken of Davy's h\st
four lectures. Faraday's letter, which has been
preserved but never publislied, is an astounding
example of the high-tlown cringing style in vogue at
that date. Davy's reply was favourable, and led to a
temporary engagement of some days as amanuensis
at the time when he was Avounded in the eye by an
explosion of the chloride of nitrogen. Faraday him-
self, nearly twent}' 3^ears afterwards, wrote* a full
account of the circumstances.
[J/. Faroda^/ to Dr. J. A. ParU]
Royal Institution, December i2;5, 18:^0.
^[Y itEAE 8ut,— You asked iiie to give you an account of
ruy tiri^t introduction to Sir H. Davj^ whicli I inn very hapjiy
to do, as I tliink the circumstances will hear testimony to his
goodness of heart.
When [ was a bookseller's apprentice, I was very fond of
experiment and very adverse to trade. It happened that a
gentleman, a member of the hoyal Institution, took nie to
hear some of Sir H. Davy's last lectures in Albemarle Street.
I took notes, and afterwards wrote them out more fairly in a
quarto volume.
'My desire to escape from trade, which I thought vicious
and seltish, and to enter into the service of Science, which I
. imagined made its pursuers amiable and liberal, induced me at
last to take the bold and simple step of writing to Sir H. Davv»
expressing my wishes, and a hope that, if an opportunity cnnie
^■- See Dr. Paris's "Life of Davy," vol. ii., p. 2 ; or Bcnce -Toiify's
■ Life and Letters of Faraday," vol. i., p. 47,
WINS FAVOUR WITPI DAVY. 11
in his way, he would favour my views ; at the same time, I
sent the notes I had taken of his lectures.
The answer, which makes all the point of my communica-
tion, I send you in the original, requesting you to take great
care of it, and to let me have it back, f.n- you may imagine
how much I value it.
Vou will observe that this took iilace at the end of the year
1812, and early in ]SI3 he requested to see me, and tohl me
of the situation of assistant in the laboratory of the luiyal
Institution, then just vacant.
At the same time that he thus gratified my desires as to
scientific employment, he still advised me not to give up the
prospects I had before me, telling me that Science Avas a harsh
mistress ; and in a pecuniary point of view but ])Oorly reward-
ing those who devoted themselves to her service. He smiled
at my notion of the superior moral feelings of philosophic men,
and said he Avoukl leave me to the experience of a few years
to set me right on that matter.
Finally, through his good efforts I went to the lioyal
Institution early in March of 1813, as assistant in the laboratory;
and in October of the same year went with him abroad as his
assistant in experiments and in writing. I returned Avith him
in April, 1815, resumed my station in the lioyal Institution,
and have, as you know, ever since remained there.
I am, dear Sir, very truly yours,
M. Faraday.
The following is Davy's note : —
Mr. P, FfAi-adaij, 183, Weymouth St., Portland Place.
December 24, 1812.
Sir, — I am far from displeased with the proof you have
given me of your confidence, and which displays great zeal,
power of memory, and attention. I am obliged to go out of
Town, and shall not be settled in town till the end of Jan^'
12 MICHAEL FARADAY.
I will then see you at any time you wish. It would gratify
me to be of any service to you ; I wish it may be in my power.
I am Sir
your obt. humble servt.
H. Davy.
Accordingly, Faraday called on Davy, who received
him in the anteroom to the lecture theatre., hy the
window nearest to the corridor. He advised him
then to stick to bookbinding^, promising to send him
books from the Institution to bind, as well as other
books. He must have been agreeably impressed,
otherwise he would not, when disabled, have sent for
Faraday to write for him. Early in 1813 the humble
household, in which Faraday lived with his widowed
mother in "Weymouth Street, was one night startled
by the apparition of Sir Humphry Davy's grand
coach, from which a footman alighted and knocked
loudly at the door. For young Faraday, who was at
that moment undressing upstairs, he left a note from
Sir Humpbry Davy requesting bun to call next
mornino-. At that interview Davy asked him whether
he was still desirous of changing his occupation, and
offered him the post of assistant in the laboratory' in
place of one who had been dismissed. The salary was
to be twenty-live shillings a week, Avith two rooms at
the top of the house. The minute appointing him is
dated March 1, 1813: —
Sir Humphry Davy has the honour to inform the managers
that he has found a person who is desirous to occupy the
situation in the Institution lately filled by William Payne.
His name is Michael Faraday. He is a youth of twenty-two
years of age. As far as Sir H. Davy has been able to observe
ENTERS ROYAL INSTITUTION. 18
or ascertain, he appears well fitted for the situation. His
habits seem good, his disposition active and cheerful, and his
manner intelligent. He is willing to engage himself on the
same terms as those given to Mr. Payne at the time of quitting
the Institution.
Resolved— That Michael Faraday be engaged to fill the
situation lately occupied by ^Ir. Payne on the same terms.*
There have come down several additions to the
story. One, probably apocryphal, says that Faraday's
first introduction to Davy was occasioned by Davy's
caUing at Riebau s to select some bookbinding, and
seeing on the shelves the bound volume of manuscript
notes of his own lectures. The other was narrated
by Gassiot to Tyndall, as follows : —
Clapham Common, Surrey,
Xovember 28, 1867.
My dear Tyndall, — Sir H. Davy was accustomed to call
on the late Mr. Pepys in the Poultry, on his way to the
London Institution, of which Pepys was one of the original
managers ; the latter told me that on one occasion Sir H. Davy,
showing him a letter, said, " Pepys, what am I to do 1 — here is a
letter from a young man named Faraday ; he has been attend-
ing my lectures, and wants me to give him employment at the
Koyal Institution — what can I do "? " " Do 1 " replied Pepys,
* His duties as laid down by the managers were these : — " To attend
and assist the lecturers and professors in preparing for, and during
lectures. Where any instruments or apparatus may be required, to
attend to their careful removal from the model-room and laboratory
to the lecture-room, and to clean and replace them after being used.
reporting to the managers such accidents as shall require repair, a
constant diary being kept by him for that purpose. That in one day
in each week he be employed in keeping clean the models in the
repository', and that all the instruments In the glass cases be cleaned
and dusted at least once within a month."
14 MICHAEL FARADAY.
"put him to wash bottles ; if he is good for anything he will do
it directly ; if he refuses, he is good for nothing. " " Xo, i^O'
replied Davy, "we must try him with something better than
that."' The result was, that Davy engaged him to assist m
the Laboratory at weekly wages.
Davj' held the joint office of Professor of Chemistry and
Director of the Laboratory; he ultimately gave up the former
to the late Professor Brande, but he insisted that Faraday
should be appointed Director of the Laboratory, and, as
Paraday told me, this enabled him on subsec^uent occasions to
hold a definite position in the Institution, in TS'hich he was
always supported by Davy. I believe he held that office to the
last.
Believe me, my dear Tjmdall, yours truly,
J. P. Gas.^iot.
In ISOS ]\Ir. latum had founded a City Philo-
sophical Society.* It consisted of thirty or forty
young men in humble or moderate rank, who met on
AVednesdays for mutual instruction ; lectures being
given once a fortnight by the menrbers in turn.
Tatum introduced Faraday' to this Society in 1813.
Edward Magrath was secretary. Amongst Faraday's
notes of his life is the followinc^ : —
o
During this spring Magrath and I established the mutual-
improvement plan, and met at my rooms up in the attics of
the Pioyal Institution, or at Wood Street at his vrarehouse. It
consisted perhaps of half-a-dozen persons, chiefly from the
City Philosophical Society, who met of an evening to read
together, and to criticise, correct, and improve each other's
^' The City Philosophical Society was given up at the time when
Mechanics' Institutes were started in London, Tatum. selhua- his
axjparatus to that estahlished in Fleet Street, the forerunner of the
Birkheck Institution, !llany of the City Society's members joined
the Society of Arts.
AT WORK IX CHEMI>TliY. 15
pronunciation and oonstmction of language. The discipline
was very sturdy, the remarks very plain and open, and the
results most valuable. This continued for several years.
He "writes, after a ^-eek of work at tlie R'.>val
Institution, to Abbott : —
Pioyal Institution. March 8, 1^13.
It is now about nine o'clock, and the thought strikes me
that the tongues are going both at Tatum's and at the lecture
in Bedford Street : but I fancy myself much better employed
than I should have been at the lecture at either (.if those places.
Indeed, I have heard one lecture already to-day, and had a
tiDger in it (I can't say a hand, for I did very little). It was
by ;Mr. Powell, on mechanic?, or rather on rotatory motion, and
was a pretty good lecture, but not very fully attended.
As I know you will feel a pleasure in hearing in what I
have been or shall be occupied. I will inform you that I have
been employed to-day, in ]iart. in extracting the sugar from a
portion of beetroot, and also in making a compound of sulphur
and carbon— a combination which has lately occupied in a
considerable degree the attention of chemists.
With respect to next "Wednesday. I shall be occupied until
late in the afternoon by Sir H. Davy, and must therefore
decline seeing you at that time ; this I am the more ready to
do as I shall enjoy your company next Sunday, and hope to
possess it often in a short time.
Tlie next letter to Abbott, dated April 9. recounts
an explosion in which both he and Sir Humphry
Davy received considerable hijury. In June he wrote
to Abbott four very remarkable letters concernincr
lectures and lecturers. He had already- heard Tatum
and Dayy, and had now assisted Brande and Pi;'weU
in their lectures, and had keenly observed their habits,
peculiarities, and defects, as Avell as the etiects they
16 :^^TCHAEL faraday.
produced on the audience. He writes without the
slightest suspicion of suggestion that he himself has
an}- likehhood of becoming a lecturer, and says that
he does not pretend to any of the requisites for such
an office. " If I am unfit for it," he sa3's, " 'tis evident
that I have yet to learn : and how learn better than
by the observation of others ? If we never judge at
all. we shall never judge right.'' " L too, have in-
ducements in the C[ity] r[hilosophioal] S[ociety] to
draw me forward in the acquisition of a small portion
of knowledge on this point." *' I shall point out but
few beauties or few faults that I have not witnessed
in the presence of a numerous assemblv."
He begins by considering the proj)er shape of a
lecture-room ; its proper ventilation, and need of
suitable entrances and exits. Then he goes on to
consider suitability of subjects and dignity of subject.
In the second of the letters he contrasts the perceptive
powers of the eye and ear, and the proper arrano;e-
ments for a lecturer's table : then considers diagrams
and illustrations. The third letter deals with the
delivery and style of the lecture, the manner and
attitudes of the lecturer, his methods of keeping alive
the attention of the audience, and duration of the
discourse. In the fourth of these letters (see p. 228),
he dwells on the mistakes and defects of lecturers,
their unnecessary apologies, the choice of apt ex-
periments, and avoidance of trivialities.
In September, 1813, after but six months of work
in the laboratory, a proposition came to him from Sir
Humphry Davy Avhich resulted in a complete chano-e
of scene. It was an episode of foreign travel, lasting
PKUFOyALS FOR FOREIGN TRAVEL. 17
as it proved, eighteen months. In the autobio-
graphical notes he wrote : —
In the autumn Sir H. Davy proposed going abroad, and
offered me the opportunity of going with him as his amanuensis,
and the promise of resuming my situation in the Institution
upon my return to England. Whereupon I accepted the offer,
left the Institution on October 13, and, after being with Sir
H. Davy in France, Italy, Switzerland, the Tyrol, Geneva, ifec,
in that and the following year, returned to England and
London April 23, 1815.
Before he left England, on Sc].)tcniber 18, 1813, at
the request of his mother, he wrote to an uncle and
aunt the folloAvino- account of himself: —
I was formerly a bookseller and binder, but am noAv turned
philosopher, which happened thus : — Whilst an apprentice, I,
for amusement, learnt a little of chemistry and otlier parts of
philosophy, and felt an eager desire to i)roceed in that way
further. After being a journeyman for six months, imder a
disagreeable master, I gave up my business, and, by the
interest of Sir H. Davy, filled the situation of chemical assistant
to the Royal Institution of Great Britain, in which office I
now remain, and where I am constantly engaged in observing
the works of Nature and tracing the manner in which she
directs the arrangement and order of the world. I have lately
had proposals made to me by Sir Humphry Davy to accompany
him, in his travels through Europe and into Asia, as philo-
sophical assistant. If I go at all I expect it will be in October
next, about the end, and my absence from home will perhaps
be as long as three years. But as yet all is uncertain. I have
to repeat that, even though I may go, my path will not pass
near any of my relations, or permit me to see those whom I so
much long to see.
To Faraday, Avho was now twenty-two years old,
foreign travel meant much more than to most young
c
18 iUCHAEL FARADAY.
men of equal age. With his humble bringing up and
slender resources, he had never had the chance of
seems: the outside "U'orld : he had never, to his own
recollection, even seen the sea. "When on Wednesday,
October 13, he started out on the journey to Ply-
mouth, in order to cross to the port of Morlaix. he
began his journal of foreign travel thus: —
This niorning formed a new epoch in my life. I have never
before, within my recollection, left London at a greater distance
than twelve miles.
This journal he kept with minute care, with the sole
purpose of recalling events to his mind. It gives full
details as to Davy's scientific friends and work, inter-
mingled with graphic descriptions of scenery : and is
remarkable also for its personal reticence. As with
many another, so with Faraday, foreii^n travel took
in his life the place of residence at a University. In
France, in Italy, he received enlarged ideas ; and
what he saw of learned men and academies of science
exercised no small formative effect upon one then at
the most impressionable age. He connnents gaily on
the odd incidents of travel : the luminescence of the
sea at night : the amazing fuss at the Custom House ;
the postilion with his jack-boots, whip, and pouch;
the glow-worm (the tirst glow-worm he had ever
seen) : and the slim pigs of ^'ormandv At Paris he
visits the Louvre, where his chief comment on its
treasures is, that by their acquisition Franco has
made herself "a nation of thieves." He o'oes to the
Prefecture of Pohce for his passport, in which he is
described as having " a round chin, a brown beard
a large mouth, a great nose/' etc. He visits the
A NEW ELE.MENT. 19
churches, Avhere the theatrical air pervading the
ph^ce "makes it impossible to attach a serious or
important feehnq to what is going on." He comments
on the wood tires, the charcoal used in cooking, the
washerwomen on the river bank, the internal decora-
tions of houses, the printing of the books. Then he
goes about with Davy amongst the French chemists.
Ampere, Clement, and Desormes come to Davy to
show him the new and strange substance " X,"
lately discovered by M. Courtois. They heat it, and
behold it rise in vapour of a beautiful violet colour.
Ampere himself, on Xovend^er 23rd, gives Davy a
specimen. They carefully note down its characters.
Dav}^ and his assistant make many new experiments
on it. At hrst its origin is kept a profound secret by
the Frenchman. Then it transpires that it is made
from ashes of seaweed. They work on it at Chevreul's
laborator}^ Faraday borrows a voltaic pile from
Chevreul. With that intuition which was character-
istic of him, l)avy jumps almost at once to a conclu-
sion as to the nature of the new body, which for
nearly two years had been in the hands of the French-
men awaiting elucidation. When he leaves Paris,
they do not wholly bless his rapidity of thought.
But Faraday has seen — with placid inditierence — a
glimpse of the great Napoleon "sitting in one corner
of his carriage, covered and almost hidden by an
enormous robe of ermine, and his face overshadowed
by a tremendous plume of feathers, that descended
from a velvet hat": he has also met Humboldt, and
he has heard M. Gay Lussac lecture to about two
hundred pupils.
20 MICHAEL FAKADAY.
Pumas has recorded in his " Eloge Historiqiie a
reflection of the impressions left by the travellers.
After speaking of the criticism to T\-hich I^avy "svas
exposed during his visit, he says : —
His laboratorj' assistant, long before he had ^von his great
celebrity by his works, had by his modesty, his amiabiUty, and
liis intelligence, gained most devoted friends at Paris, at
Geneva, at Montpelher. Amongst these may be named in
the front rank ^M. de la Rive, the distinguished chemist, father
of the illustrious physicist whom we count amongst our foreign
associates. The kindnesses with which he covered my youth
contributed not a httle to unite us — Faraday and myself.
With pleasure we u^ed to recall that we made one another's
acquaintance under the auspices of that affectionate and helpful
philosopher whose example so truly witnessed that science
does not dry up the heart's blood. At Montpellier, beside the
hospitable hearth of Berard, the associate of Chaptal, doyen
of our corresponding members, Faraday has left memories
equaUy charged with an undjing sympathy which his master
could never have inspired. We admired Davy, we loved
Faraday.
It is December 29 when the travellers leave Paris
and cross the forest of Fontainebleau. Faradav thinks
he never saw a more beautiful scene than the forest
dressed in an aiiy garment of cr3-stalline hoar frost.
They pass through Lyons, Montpellier, Ais, Xice,
searching on the way for iodine in the sea-plants of
the Mediterranean. At the end of January, 1S14,
they cross the Col de Tende over the snow at an
elevation of 6,000 feet into Ital}-, and And themselves
in the midst of the Carnival at Turin. Thev reach
Genoa, and go to the house of a chemist to make
experiments on the ram torpedo, the electric skate,
WITH DAA'Y IN ITALY. 21
trj'ing to ascertain Avhether Avater could be decom-
posed by the electrical discharges of these singular
Hshes. From Genoa they go by sea to Lei'ici in an
open boat, with niuch discomfort and fear of ship-
wreck ; and thence by land to Florence.
At Florence he goes with Davy to the Accademia
del Cimento. He sees the library, the gardens, the
museum. Here is Galileo s own telescope — a simple
tube of paper and wood, with lenses at each end —
with which he discovered Jupiter's satellites. Here is
the great burning glass of the Grand Duke of Tuscany.
And here is a numerous collection of magnets, includ-
ing one enormous loadstone supporting a weight of
150 pounds. They make ''the grand experiment of
burning the diamond " in oxygen by the sun's heat
concentrated through the Grand Duke's burning
glass. They find the diamond to be pure carbon.
Then early in April they depart for Rome.
From Home Faraday wrote to his mother a long
chatty letter summarising his travels, and sending
messages of kindly remembrance to his old master
Riebau and others. He tells how, in spite of political
troubles, Sir Humphry Davy's high name has pro-
cured them free admission everywhere, and how they
have just heard that Paris has been taken by the
Allied troops.
At Rome they witness unconvinced some attempts
of Morichini to impart magnetism to steel needles
by the solar rays. They pass the Colosseum by moon-
light, making an early morning start across the
Campagna, on the road to Naples, with an armed
guard for fear of brigands. Twice, in the middle of
22 MICHAEL FARADAY.
^lay, they ascend A'csuvius, the second time during
a partial eruption rendered all the more vivid by the
lateness of the hour — half-past seven — at which the
edge of the crater was reached. In June they visit
Temi, and note tho nearly circular rainbow visible in
the spray of the cataract ; and so across the Apennines
to Milan,
At ]\Ii]an occurs the following entry: —
Friday 17th [June, 1814], Milan. Saw M. Volta, who carne
to 8ir H. Davy, an hale elderly man, bearing the red ribbon,
and very free in conversation.
He does ruA record how tbo ceremonious old Count,
who had specially attired himself in his Court uni-
form to welcor/io the illustrious chemist, Avas horrified
at the informal manners and uncourtly dress of tlic
tourist philosopher.
So, travelling' by Como and Doruo d'Ossola, they
come to Geneva, and here remain a long time;
and Faraday Avritcs again to his mother and to
Abbott. He can even find time to discuss witlj the
latter the relative merits of the French and Italian
languages, and the trend of civilisation in Paris and
in Rome. Twice he sends messages to Riebau. One
of his letters to Abbott, in September, contains
passages of more than transient interest : —
Some doubt.-, have been exj'reftsed to me lately with renpect
to the continuance of the iioyal Inntitution ; Mr. Xewrnan can
I^robably give a guesH at the i-.-.ue of them. J have three boxe«
of books, (fee, there, and I -Jjould be norry if they were lo-.t by
the turning uji of unforeseen circum«tanceH ; but f hoj>f; all
will hh(\ well ^you will not read thi« out aloud). Remember
HINTS OF DTSCOMFORT. 23
me to all friends, if you please. And " now for you and I to
ourselves." ...
In passing through life, my dear friend, everyone must
expect to receive lessons, both in the school of jirosperity and
in that of adversity ; and, taken in a general sense, these
schools do not only include riches and poverty, but everything
that may cause the happiness and pleasure of man, and every
feeling that may give him pain. 1 have been in at the door of
both these schools ; nor am T so far on the right hand at present
that I do not get hurt by the thorns on my left. With respect
to myself, I have always ])erccived (when, after a time, I saw
things more clearly) that those things which at first appeared
as misfortunes or evils ultimately were actually benefits, and
productive of much good in the future progress of things.
Sometimes I compared them to storms and tempests, which
cause a temporary disarrangement to produce permanent good ;
sometimes they aftpeared to me like roads — stony, uneven,
hilly, and uncomfortable, it is true — but tlie only roads to a
good beyond them ; and sometimes I said they were clouds
which intervened between me and the sun of prosperity, but
which I found were refreshing, reserving to me that tone and
vigour of mind which prosperity alone would enervate and
ultimately destroy. . . .
You talk of travelling, and I own the word is seducing, but
travelling does not secure you from uneasy ciicumstances. I
by no means intend to deter you from it ; for though I should
like to find you at home when I come home, and though I
know how much the loss would be felt by our friends, yet I
am aware that the fund of knowledge and of entertainment
opened would be almost infinite. But I shall set down a few
of my own thoughts and feelings, (fcc, in the same circum-
stances. In the first place, then, my dear B., I fancy that
when I set my foot in England I shall never take it out again ;
for I find the prospect so different from what it at first
appeared to be, that I am certain, if I could have foreseen the
things that have passed, I should never have left London. In
the second pl^ce, enticing as travelling is— and I appreciate
fully its advantages and pleasures— I have several times been
"24 iMU'UAKl, FAKAPAV.
iiunv than hulf ilroiaeil to roturn liiustily home: but socoin!
thou.i^hts liavo still iiiaiu'i-.l mo to try wlint tlio fniuiv may
produce, ami now 1 am only rrtainod 1>>' tlio ^vislt i>l improvo-
mont. 1 ha\c loarm'd Just enough to lu-rroivo my i.i;norani'o,
ami, asliamod (^f my dofocls in ovi'r> tliin-;, 1 wish to soizo t.lio
opportunity of remodyin^^' tbom. The litllo km>wlodi:co 1 hivvo
gained in la.ni;nai;vs makes nie wish to know more ol them,
and the little I have seen o'i men and manners is jnst enough
to make me desirous of seeing more ; added to wdiieli, the
glorious opportunity 1 enjoy of iini>ro\ iug in the know^Iodgo ot
ehemistry and the seieuees e(tntinually deUMnun(\s nu' to
tiuish this voyage with Sir llumithry Davy. Hut if I wisli to
enjoy those advantages, 1 liavo to saeriliee uuu'li ; a,ud tliough
those saorilices are sueli as an humblo man would not feel, yt^t
I cannot (piietty make them. Travelling, toti, 1 find, is almost
inconsistent with i-eligittn (1 uieun modern travelling), and 1
am yet so old-fashioned as to remember atnmgly (1 hope
perfectly) my youthful education ; and upon tim wholly iii<i/</r<'
the a,dvant'iges of travelling, it is not. impossible but that ytiii
may see mo at your door when you expei't a, letter.
\ou will perceive, dear H., that I do not wish you hawtily
to leave your present situa.! ion, because 1 tinidc that. a. Iiasty
change will only make things worse. ^'^^u will naturally
compare your situation with otliers you sec artmnd you, and
by this comparison your own will a.]ipcar mon^ sad, whilst the
others st-em brighter than in truth they are ; for, like the two
poles of a battery, the ideas of eucli will become t^xalted by
apitroaching them. Hut I hrave you. dear friend, to act. in
this case as your judgnuait may direct, honing alway.s for
the best.
Sir llumpliry works often on iodine, and has hitely been
making experiments on the j>riHmatic spt^ctrum at IM. Tietet's.
They are not yet jierfeeted, but fi'om the use of very delicate
air thermometers, it appears tlint the rays i)ro(hu',ing most
heat are certainly out of tlio spC:t;trum and la^yond the red
ra.ys. Our time has been employed lately in lishing and
shooting; and many a (pmil has been killed in the plains n\'
ARISTOCRATIC HAUTEUR. 25
Geneva, and many a trout and grayling have been pulled
out of the Khone.
1 need not say, dear lien, how perfectly I am yours,
M. Faeaday.
This letter reveals, what the diary of travel so
scrupulously hides, the existence of cu'cuinstances
Avhich were hardl}^ tolerable in Faraday's position.
To make the reference intelliiiible it should be re-
inenibered that Davy, who had come up to London
in 1801 as a raw youth, of immense ability but xery
uncouth exterior, had developed into a fashionable
person, had become the idol of the hour, had married
a very wealthy widow, had been knighted, and had
given himself up very largely to the pursuits of
fashionable society and to the compan}^ of the aristo-
cratic hcdii vionde. Lady Davy accompanied Sir
Humphr}^ in this Continental tour ; and though
Faraday had been taken with them as secretary and
scientific assistant, it would seem that he had not
always been treated with the respect due to one in
that position. The above letter evidently disquieted
Abbott, for he wrote back to Faraday to inquire more
closely into his personal affairs, telling him he was
sure he was not happy, and asking him to share his
difficulties. Farada}-, who was now back in Eome,
replied in January in a long letter of twelve pages,*
'• Two passages may be quoted. "Finally, Sir H. has no valet
except myself . . . and 'tis the name more than the thing -which
hurts." " ^Vhe^ I return home, I fancy I shall return to my old
profession of hoolvseller, for books still continue to please me more
than anything else."
26 MICHAEL FARADAV.
■which he says he had mteuded to till with an account
of the waterfalls he had seen, but which gives instead
a detailed account of his vexations. He had, he
said, written his former letter when in a ruffled state
of mind. He now gives the explanation. Betore,
however, this letter could reach Abbott, the latter
had written 3-et more urgently to know what was the
matter. To this Faraday replied on February 23rd.
As this shorter letter summarises the previous one
it may be given here. Both are printed in Bence
Jones's ''Life and Letters ": —
home, February ^13, 1815.
Dear B , — In a letter of above twelve pages I gave
ausAvers to your rjue.stion re-^iieetiiig my .situation. It was a
subject not wurtb talking about, but I consider your inquiries
as so many proofs of your kindness and the interest you take
in my vv'elfare, and I thought the most agreeable thanks I
could make you would be to answer them. The same letter
also contained a short account of a paper written by Sir
Humphry Davy on ancient colours, and some other miscel-
laneous matters.
I am quite ashamed of dwelling so often on my own afFairs,
but as I know you wish it, I shall brietiy inform you of my
situation. I do not mean to employ much of this sheet of
1 taper on the subject, Ijut refer you to the before-mentioned
long letter for clear information. It happened a few daj's
before we left Encrlan'l, that Sir Hi's valet declined going vrith
him, and in the sliort space of time allowed by circumstances
another could not be g(jt. Sir H. told me he was very sorrv
but that, if I would do such things as "were absolutely' necessary
for him until he got to Paris, he should there get another. I
murmured, but agreed. At Paris he could not get one. Xo
Englishmen were there, and no Frenchman tit for the place
could talk English to me. At Lyons he could not get one -
at Montpellier he could not get one ; nor at Genoa, nor at
SECRET OF MORTIFICATIOX. 27
Florence, nor at liome, nor in all Italy; and^believe at last
he did not wish to get one : and we are just the same noAv as
we were when he left England. This of course throws things
into my duty which it was not my agreement, and is not my
wish, to perform, but AA'hich are, if I remain with Sir H.,
unavoidable. These, it is true, are very few ; fur having been
accustomed in early years to do for himself, he continues to do
so at present, and he leaves very little for a valet to perform ;
and as he knows that it is not pleasing to me, and that I do
not consider myself as obliged to do them, lie is always as
careful as possible to keep those things from me Avhich he
knows would be disagreeable. But Lady Davy is of another
humour. She likes to show her authority, and at first I found
her extremely earnest in mortifying me. This occasioned
quarrels betAveen us, at each of which I gained ground, and
she lost it ; for the fretpiency made me care nothing about
them, and weakened her authority, and after each she behaved
in a milder manner. Sir H. has also taken care to get servants
of the country, ycle])ed lacquais de place ^ to do everything slie
can want, and now I am somewhat comfortable ; indeed, at
this moment I am perfectly at liberty, for Sir H. has gone to
Xaples to search fur a house or lodging to which we may
follow him, and I have nothing to do but see Eome, write my
journal, and learn Italian.
But I will leave such an unprofitable subject, and tell you
what I know of our intended route. For the last few weeks it
has been very undecided, and at this moment there is no
knowing which way we shall turn. Sir H. intended to see
Greece and Turkey this summer, and arrangements were half
made for the voyage ; but he has just learned that a quarantine
must be performed on the road there, and to do this he has
an utter aversion, and that alone will perhaps break up the
journey.
Since the long letter I wrote you. Sir H. has written two
short papers for the Koyal Society — the first on a new solid
compound of ioditie and oxygen, and the second a new gaseous
2s MICHAEL FAP.ADAY
compound of chlorine and oxygen, which contains four tunes
as much oxygen as euchlorine.
The discovery of these bodies contradicts many parts of
( lay-Lussac's paper on iodine, which has been very much
vaunted in these parts. The French chemists were not aware
of the importance of the subject until it was shown to them,
and no^^ they are in haste to reap all the honours attached
tr. it : but their liaste opposes their aim. They reason theo-
retically, without demonstrating experimentally, and errors are
the result.
I am. my dear Friend, yours ever and faithfully,
!M. Farapay.
The equivocal position thus forced upon Faradaj'
by the hauteur of Lady Davy nearl}- caused a contre-
temps during the stay at Geneva, which lasted from
the end of June, 1814, to about the middle of
September. Bence Jones's account, derived fi*om
Faraday himself, is as follows : — Professor G. de la
Rive, nndazzled by the brillianc}' of Davy's reputation,
was able to see the true worth of his assistant. Dav}'
was fond of shooting, and Faraday, who accompanied
them, used to load l)avy's gun for him, while De la
Rive loaded his own. Entering into conversation
with Faraday, De la Rive was astonished to find that
the intelligent and charming young man whom he
had taken hitherto for a domestic was reall}' ixrepara-
teur de lahoratoire in the Royal Institution. This
led him to place Faraday, in one respect, on an
equality with Davy. Whilst the}' were staying in his
house, he wished them to dine together at his table.
Davy, it is said, dechned, because Farada}' acted in
some things as his servant. De la Rive expressed
VISIT TO GENEVA. 29
his feelings strongly, and ordered dinner in a separate
room for Faraday. A rumour spread years after that
JJq la Rive gave a dinner in Faraday's honour : this is
not so, however.
Of that Geneva visit Faraday says, in 1858, to M.
A. de la Rive : — •
I have some such thoughts (of gratitude) even as regards
your own father, Avho was, I may say, the first who personally
at Geneva, and afterwards by correspondence, encouraged and
by that sustained me.
This correspondence, which began with the father
and was continued with the son, lasted altogether
nearly fifty years.
From Geneva the travellers went northward, by
Lausanne, Vevay, Bern, Zurich, and Schaffhausen,
across Baden and Wtirtemburg to Munich. After
visiting this and other German towns, they crossed
Tyrol southwards to Vicenza, halting in the neigh-
bourhood of the Pietra Mala to collect the in-
flammable gas which there rises from the soil.
They spent a day in Padua, and three days in Venice ;
and on by Bologna to Florence, where Davy com-
pleted his analysis of the gas collected at Pietra Mala.
Early in November they were again in Rome. He
writes once and again to his mother, while his anxiety
about the Royal Institution makes him send inquiries
to Abbott as to what is going to happen there, and to
charge, him, "if any change should occur in Albemarle
Street," not to forget his books which are lying there.
" I prize them now more than ever."
To his former master, Riebau, he wrote from Rome
as follows : —
30 MICHAEL FARADAY.
Eome, Jan. 5tb, ISlo.
Honoured Sir,
It is with very peculiar but very pleasing and
indee<^ flattering sentiments that I commence a letter intended
for you, for I esteem it as a bigb honour that you should not
only allow but even wish me to write to you. During the
whole of the short eight years that I Avas with you, Sir, and
during the year or two that passed afterwards before I left
England, I continually eujoyed your goodness and the eflfects
of it ; and it i> gratifying to me in the highest degree to find
that even absence has not impaired it, and that you are willing
to give me the highest proof of (allow me to say) friendship
that distance will admit. I have received both the letters that
you have wrote to me. Sir, and consider them as far from
being the least proofs of your goodwill and remembrance of
me. Allow me to thank you humbly but sincerely for these
and all other kindness, and I hope that at some future day
an opportunity will occur when I can express more strongly
my gratitude.
I beg leave to return a thousand thanks to my kind
Mistress, to Mr. and Mrs. Paine and George for their re-
meuibrances, and venture to give mine with respect in return.
I am very glad to hear that all are well, I am very much
afraid you say too much of me to Mr. Dance, Mr. Cosway,
Mrs. Udney, etc., for I feel unworthy of what you have said of
me formerly, and what you may say now. Since T have left
England, the experience I have gained in more diversified and
extended life, and the knowledge 1 have gained of what is to
be learned aud what other^i know, have sufficiently shown me
my own ignorance, the degree in which I am surpassed by
all the world, and my want of powers ; but I hope that at
least I shall return home with an addition to my self-know-
ledge. When speaking of those who are so much my superiors
as Mr. Dance, Mr. Cosway, and Mrs. Udney, etc., I feel a
continual fear that I should appear to want respect, but the
manner in which you mention their names in your letter
emboldens me to beg that you will give my humblest respects
BOOKS AND BOOKSELLERS. 31
to those honoi'ed persons, if, and only if (I am afraid of
intruding) they should again speak of me to you. Mr. Dance's
kindness claims my gratitude, and T trust that my thanks, the
only mark that I can give, will be accepted.
Since I have been abroad, my old profession of books has
oftentimes occurred to my mind and been productive of much
])leasure. It was my wish at iirst to purchase some useful
book at every large town we came to, but I found my stock
increase so fast that I was obliged to alter my plan and purchase
only at Capital Cities. The first books that I wanted A\ere
grammars and dictionaries, but I found few jilaces like London
v/here I could get whatever T wanted. In France (at the time
we were there) English books were very scarce, and also
English and French books ; and a French grammar for an
Englishman was a thing difficult to hnd. Nevertheless the
shops appeared well stocked with books in their own language,
and the encouragement Napoleon gave to Arts and Sciences
extended its influence even to the printing and binding of
books. I saw some beautiful specimens in both these branches
at the Biblioth^ue Imperiale at Paris, but I still think they
did not exceed or even equal those I had seen in London
before. We have as yet seen very little of Geiinany, having
passed rapidly through Switzerland and stojipino: but a few
days at Munich, but that little gave me a very favorable idea
of the Booksellero' shops. I got an excellent English and
(ierman dictionary immediately I asked for it, and other books
I asked for I found were to be had, but E. and G. Grammars
were scarce, owing to the little communication between the
two Em])ires, and the former power of the French in Germany.
Italy I have found the country furnished with the fewest
means— if books are the means of disseminating knowledge,
and even A^enice which is renowned for Printing appeared to
me bare and little worthy of its character. It is natural to
suppose that the great and most estimable use of printing is to
produce those books which are in most general use and which
are required by the world at large ; it is those books which
form this branch of trade, and consequently every shop in it
gives an account of the more valuable state of the art (i.e.) the
32 MICHAEL FAKADAY.
use ruiide of it. In Italy there are many book:>, and the
shelves of the shops there appear full, but the books are old,
or what is new have come from France : they seem latterly to
have resigned printing and to have become satisfied with the
libraries their forefathers left them. I found at Florence an E.
and I. Grammar (Veneroni's), which does a little credit to
Leghorn : but I have searched unsuccessfully at Rome, Naples,
Milan, Bologna. Venice. Florence, and in every part of Italy
for and E. an I. Dictionary, and the only one I could get was
Kollasetti in Svo. E. F. and I. A circumstance still more
singular is the want of bibles ; even at Rume, the seat of the
Roman Catholic faith, a bible of moderate size is not to be
found, either Protestant or Catholic. Those which exist are
large folios or 4tos and in several volumes, interspersed with
the various readings and commentaries of the fathers, and they
are in the possession of the Priests and religious professors.
In all shops at Rome where I ask for a small pocket bible the
man seemed afraid to answer me, and some Priest in the shop
looked at me in a very inquisitive way.
I must now, Kind Sir, put an end to this Ittter, which I
fear you will think already too long. I beg you will have the
goodness to send to my blether and say I am well, and give
my duty to her and my love to my brother and sisters. I have
wrote four or five times lately from Rome to various friends.
Remember me. if you please, to Mr. Kitchen, and others who
may encpiire after me. I thank you for your concluding
wishes and am, Sir.
Your most dutifully.
Faeaday.
To his sisters he wrote also. To the elder, on the
Lhurch festiYals. the CamiYal, aud the ruins of the
Colosseum. To the younger, on the best way of
learning French. His diary is full of the CarniYal,
the foolishness of whicdi attbrded him much amuse-
ment. He witnessed the horse-races in the Corso,
went four tunes to masked balls, where his boyish
TIIK EN'J) OK 'J'llK TOUIJ. 'Ml
love of uproarious fun broke out beyond restraint, for
to the last one he went disguised in a night-gown and
night-cap. Between gaieties in the evenings and
chemical experiments with Davy in the day, his time
must have been pretty fully occupied. They had had
the intention of going on to (Ireece and Turkey, but
owing to dread of quarantine these projects were
abandoned, and at the end of Februaiy, 1S15, they
moved southwards to Naples. Here is a characteristic
entry : —
Tuesday, March 7th. — I heard for news that J3onaparte was
again at liberty. Being no politician, I did not trouble myself
much about it. though I suppose it will have a strong influence
on the affairs of Europe.
He went with Sir Humphry to explore Monte Somma,
and ventured to make another ascent of the cone
of Vesuvius, with the gratification of finding the crater
in much greater activity than during the visits of the
preceding year.
Then, for reasons not altoirether clear, the tour was
suddenly cut short. Naples was left on March 21st,
Rome on 24th, Mantua was passed on 80th. Tyrol
was recrossed, Germany traversed by Stuttgardt,
Heidelberg, and (Jologne. Brussels w^as reached on
16th April, whence London was regained via Ostend
and Deal. A letter written from Brussels to his
mother positively overflows with the joy of expected
return. He does not want his mother to be inquiring
at Albemarle Street as to when he is expected : —
You may be sure that my first moments will be in your
company. If you have opportunities, tell some of my dearest
D
o4 MICHAEL FAUADAV.
fiiends, but do uot tell everybody— that i.-, do aut trouble
yourself to do it. I am of uo consequeuce except to a lew,
aud there are but a few that are of consequeuce to me, and
there are some whom I should like to be the first to tell myself
—Mr. Eiebau for one. However, let A. know, if you can. . .
Adieu till I see you, dearest Mother : and believe me ever
your atiectionate and dutiful son, M. Faeaday.
[P.S.] Tis the shortest and (to me, the sweetest letter I
ever wrote you.
A fortnight after his" return to London. Faraday
was re-engaged, at a sahiry of thirty shilHngs a week,
at the Pioyal Institution as assistant in the h^boratory
and mineralogical collection. He returned to the
scene of his former labours: but with what widened
ideas ! He had had eicfhteen months of daily inter-
course with the most brilhant chemist of the age.
He had seen and conversed with Ampere, Arago,
Gay-Lussac, Chevreul, Dumas, Volta, De la Rive,
Biot. Pictet, De Sausstire. and De Stael. He had
formed a lasting friendship with more than one ot
these. He had dined with Count Rumford, the
founder of the Royal Institution. He had gained
a certain mastery over foreign tongues, and had seen
the ways of foreign society. Though it was many
A'ears before he again quitted England for a foreign
tour, he cherished the most hvelv recollection ot
manv of the incidents that had befallen him.
CHAPTER IL
LIFE AT THE ROYAL INSTITUTION.
Amongst the scientific societies of Great Britain,
the Royal Institution of London occupies a con-
spicuous place. It has had many imitajtors in its time,
yet it remains unique. A " learned society " it may
claim to be, in the sense that it publishes scientific
transactions, and endeavours to concentrate within
itself and promote the highest scieiice, within a
certain range of subjects. In some respects it re-
sembles a college ; for it appoints professors, and
provides them with space, appliances, and materials
for research, and a theatre wherein to lecture. For
its members it provides a comfortable, well-stocked
library, and a reading-room where daily and periodic
journals may be consulted. But it has achieved a
reputation far in excess of any it would have held,
had that reputation depended solely on its publica-
tions, or on the numerical strength of its membership.
Founded in the 3^ear 1799 by that erratic genius
Count Ruinford, as a sort of technical school,* it
would speedily have come to an end had not others
stepped in to develop it in new ways. From the
certain ruin which seemed impending in 1801, it was
* The meeting at which it was actually originated was held under
the ijresidency of Sir Joseph Banks, P.R.S., nominally as a meeting
for the Assistance of the Foot !
ob ^t[^.HAEL KAUAI >AV.
saved by the appearance upon the scene of the
briUiant youth Humphry Davy, whose lectures made
it for ten years the resort of fashion. In 1^14 it was
again in such low water that Faraday, traveUing on
the Continent at that time as amanuensis to Sir
Humphry, was every n\onth expecting to hear of
its collapse. Until about 1833, when the two FuUerian
Professorships were founded, it was continually m
rinancial ditticulties. The persistent and extraordinary
ehorts made by Faraday from 182G to 1839; and the
reputation of the place Avhich accrued by his dis-
coveries, were be^'ond all question its salvation
from ruin. When it was founded it was located in
two private houses in Albemarle Street, then regarded
as quite out of town, if not almost suburban: the
premises being altered and an entrance hall ^ntll
staircase added. A httle later the lecture- theatre,
much as it still exists, was constructed. The exterior
at lirst remained unchanged. The stucco pilasters of
Grecian style, which give it its ah of distinction,
were not erected until 1838. The fine rooms of the
I)avy-Faraday laboratory at the south end were only
added in 1896 by the liberality of Mr. Ludwig Mond.
Besides the laboratories for research in physical
chemistry, Avhich have thus been associated with the
older part of the Institution, additional rooms for the
library have been provided in this munificent cr-ift to
science. The older laboratories of the Institution,
though they retain some features from Rumford's
time, have been considerably remodelled The old
rooms where Dav}', Young, Brande, Faraday, Frank-
land, and T^^ldaIl conducted then- researches are still
KOYAL INSTITUTION LAIJOKATORIES. 87
in existence ; but the chief laboratory was recon-
structed in 1872 in Tjaidall's time ; and it has been
quite recently enlarged and reconstructed to accom-
modate the heavy machinery required in Professor
Dewar's researches on liquid air and the properties of
bodies at low temperatures.
The spirit of the place ma}^ be sunjmed up very
briefly. It has existed for a century as the home
of the highest kind of scientific research, and of
the best and most specialised kind of scientitic
lectures. It was here that Davy fij-st showed the
electric arc lamp : that he astonished the world by
decomposing potash and producing potassium; that
he invented the safety lamp. It was here that
Faraday \vorked and laboured for nearly Mlty years.
Here that Tyndalls investigations on radiant heat
and diamagnetism were carried on. Here that Brande,
Frankland, Odling, Gladstone, and Dewar have handed
on the torch of chemistry from the time of Davy.
Professorships, of which the educational duties are
restricted to a few lectures in the year, giving leisure
and scope for research as the main dut}^ are not to be
found anywhere else in the British Islands ; those at
colleges and universities being invariably hampered
Avifch educational and administrative duties.
As for the lectures at the Pioyal Institution, they
may be divided under three heads : the afternoon
courses; the juvenile lectures at Christmas; the
Friday night discourses. The afternoon lectures are
thrice a week at three o'clock, and consist usually of
short courses, from three lectures to as many as twelve,
by eminent scientific and literary men. Invariably
38 MICHAEL FARADAY.
one of these courses during the season, either before
or after Easter, is given by one of the regular Pro-
fessors ; the remaining lecturers are paid professional
fees in proportion to the duration of their course.
The Christmas lectures, always six in number, are
given, sometimes by one of the Professors, sometimes
by outside lecturers of scientific reputation. But
the Friday night discourses, given at nine o'clock,
during the season from January till June, are unique.
Xo fee is paid to the lecturer, save a contribution
toward expenses if applied for, and it is considered to
be a distinct honour to be invited to crive such a
discourse. There is no scientific man of any origii:ial
claim to distinction: no chemist, engineer, or electrician:
no phvsioloo'ist, creoloo^ist, or mineralooist, during the
last fifty years, who has not been mvited thus to give
an account of his investio^'ations. Occasionallv a
wider range is taken, and the eminent Avriter of books,
dramatist, metaphysician, or nuisiciau has taken his
place at the lecture-table. The Friday night gather-
ing is always a brilliant one. From the salons of
society, from the world of politics and diploiiiacy, as
well as from the ranks of the learned professions and
of the tine arts, men aiid women assemble to listen to
the exposition of the latest discoveries or the newest
advances in philosophy' by the men who have made
them. Every discourse must, so far as the subject
admits, be ilhistrated in the best possible way by
experiments, by diagrams, by the exhibition of
specimens. Not infrequently, the person invited to
give a Friday evening discourse at the Royal Institu-
tion will begin liis preparations live or six months
THE FAMOUS I.KrTrUES. 39
beforehand. At least one instance is known — the
occasion being a discourse by the late Mr. Warren De
la Rue — where the preparations were begun more
than a 3^ear beforehand, and cost several hundreds of
pounds. And this was to illustrate a research already
made and completed, of which the bare scientific
results had already been communicated in a memoir
to the Royal Society. A mere enumeration of the
eminent men Avho have thus given their time and
labours to the Royal Institution would till many
pages. It is little cause for wonder then that the
lecture- theatre at Albemarle Street is crowded week
after week in the pursuit of science under condi-
tions like these ; or that every lecturer is spurred
on by the spirit of the place to do his subject the
utmost justice by the manner in which ho handles
it. There are no lectures so famous, in the best
sense of the word so popular, certainly none sus-
tained at so high a level, as the lectures of the Royal
Institution.
But it was not always thus. Davy's brilliant but
ill-balanced genius had drawn fashionable crowds
to the morning lectures which he gave. Brande
proved to be a much more humdrum lecturer ; and
though with young Faraday at his elbow he found
his work of lecturing a task " on velvet," he was
not exactly an inspiring person. During Davy's
protracted tour abroad things had not altogether
prospered, and his return was none too soon. Faraday
threw himself whole-heartedly into the work of the
Institution, not only helping as lecture assistant, but
giving a hand also in the preparation of the Quarfaiif
40 JllCIIAEL FAKAPAV.
JoHi-ti(d of Science, which had been cstabhshcd as a
kind ot'journal of proceedings.
But now Faraday was to take a quiet step forward.
He appears at the City Philosophical Society in the
character of lecturer. He oave seven lectures there,
in 1816, on chemistry, the fourth of them being "On
Radient Matter." Extracts arc oiyen from most of
these lectiu'cs in Bence Jones's " Life and Letters of
Faraday " ; they show all that love of accuracy, that
Ithilosophic suspense of judgment in matters of
liypothesis, which in after 3'"ears were so characteristic
mF the man.
He alsi ) l;cpt a c< )i in uonplacc b( )ok tilled Avith
II' ties of scientific matters, with literary excerpts,
;uiagrams, epitaphs, algebraic puzzles, varieties of
spelling of his own name, and personal experiences,
including a poetical diatribe against falling in love,
together with the following more prosaic aphorism : —
What iy Love ? — A nuisance to everybody but the parties
concenied. A private aflair which every one but those con-
cerned wishes to make public.
It also includes a piece in verse, by a member of
the City Philosophical Society -^a Mr. Dryden — called
'■ <^)uarterly Night," which is interesting as embalming
a portrait of the youthful Faraday as he appeared to
his coim'ades : —
Neat was the youth in dress, in person phiin ;
His eye read thus, Phllomplw in (jrain;
Of understanding clear, reflection deep ;
Expert to apprehend, and strong to keep.
His watchful mind no subject can elude,
Nor s])ecious arts of sophists ere delude ;
CITY PHILOSOrHlOAL SOCIETY. 41
His powers, unshackled, range from pole to pole ;
His mind from error free, from guilt his soul.
Warmth in his heart, good humour in his face,
A friend to mirth, but foe to vile grimace ;
A temper candid, manners unassuming,
Always correct, yet always uniiresuming.
Such was the youth, the chief of all the lj;uid ;
His name well known, Sir Hum]fhry"s right hand.
At this date there were no evening duties at the
Royal Institution, but Faraday found liis evenings
w^ell occupied, as he explains to Abbott when rallied
about his having deserted his old friend. Monday
and Thursday evenings he spent in self-improvement
according to a regular plan. Weduesda3\s he gave to
" the Society " (i.e. the C'ity Philosophical). Satur-
days he spent with his mother at Weymouth Street ;■
leaving only Tuesdays and Fridays for his own
business and friends.
And so the busy months pass, and he gives more
lectures in the privacy of the <Jity Society, one of
them, "(Jn some Observations on the Means of obtain-
ing Knowledge," attaining the dignity of print at the
hands of Effingham Wilson, the enterprising City
publisher, who a few years later printed Browning's
'' Paracelsus " and Alfred Tennyson's first volume,
" Poems : Chiefly Lyric-al." By the time he has given
nine lectures he has gained confidence. The discourses
had all been written out beforehand, though never
literally "read." For the tenth lecture^ori (Jarbon —
he wrote notes only. This is m July, 1817, and in these
notes he tenches on a matter in Avhich he had been
very busily aiding Sir Humphry Davy, the invention of
42 MK'HAEf. FARADAY.
the safety lamp. Islany of the early forms of experi-
mental apparatus constructed, and some of the early
lamps, are still preserved in the museum of the Royal
Institution. Dr. Clanny had, in 1813, proposed an
entirely closed lanip, supplied with air from the mine,
throup^h water, by belloAvs. After many experiments
on explosive mixtures of gas and air, and on the
properties of flame, Havy adopted an iron-wire gauze
protector for his lamp, which was introduced into
coal mining early in 1816. In Davy's preface to his
work describing it, he says : '* I am myself indebted
to Mr. Michael Faraday for much able assistance in
the prosecution of my experiments."
And well might Davy be grateful. With all his
iuunense ability, he was a man almost destitute of
the faculties of order and method. He had little
self-control, and the fashionable dissipations which he
permitted himself lessened that little. Farada}^ not
only kept his experiments going, but made himself
responsible for their records. He preserved every
note and manuscript of Davy's with religious care.
He copied out Davy's scrawled researches in a neat
clear delicate handwriting, begging only for his pains
to be allowed to keep the originals, which he bound
in two cpiarto volumes. Faraday has been known
to remark to an intimate friend that amongst his
advantages he had had before him a model to teach
him what he should avoid. But he was ever loyal to
Davy, earnest in his praise, and frank in his acknow-
ledgnient of liis del.it to his master in science. Still
there arose th(3 little rift within the lute. The safety
lamp, great as was the practical advantage it brought
A RIFT WITHIN THE LUTE. ^o
to the miner, is not safe in all circumstances.
Davy did not like to admit this, and would never
acknowledge it. Examined before a Parliamentary
Cormuittee as to whether under a certain condition
the safety lamp would become unsafe, Faraday
admitted that this was the case. Not even his
devotion to his master would induce him to hide the
truth. He was true to himself in making the acknow-
ledgment, though it angered his master. One Friday
evening at the Royal Institution — probably about
1826 — there was exhibited an improved Davy lamp
with a eulogistic inscription ; Faraday added m pencil
the words : " The opinion of the inventor."
At this time he began to give private lessons in
chemistry to a pupil to whom he had been recom-
mended by Dav3^ His lectures at the City Society in
Dorset Street were continued in 1818, and at the
conclusion of those on chemistry he delivered one on
" Mental Inertia," which has been recorded at some
length by Eencc Jones.
In 1818 he attended a c<.»urse of lessons i.>n oratory
by the elocutionist Mr. B. H. Suiart, paying (jut of his
slender resources half a guinea a lesson, so anxious
was he to improve himself, even in his manner of
lecturing. His notes on these lessons fill 133 manu-
script pages.
His other notes now begin to ]3artake less of the
character of quotations and excerpts, and more of the
nature of queries or problems for solution. Here are
some examples ; —
'■ Do the pith balLs diverge by the disturbance of electricity
in consequence of mutual induction or notT'
44 :\ncHAEL fahaday. ^
" Distil oxalate of ammonia. Query, results? "
" Query, the nature of the body Phillips Iturns in his spirit
lamp?"
The Phillips here lUGiitioiied was the chemist
Richard Phillips (aftenvards President of the Chemi-
cal Society), one of his City friends, whose name so
frequently occurs in the correspondence of P'araday's
middle life. Phillips busied himself to promote the
material interests of his friend Avho — to use his own
language — was " constantly engaged in observing the
Avorks of Nature, and tracing the manner in which she
directs the arranc^ement and order of the Avorld," on
the splendid salary of £100 per annum. The folloAV-
ing note in a letter to Abbott, dated February 27, 1818,
reveals new professional labours : —
I lia\'e been more than enough employed. We have l)een
ubli^^ed even to put aside lectures at the Institution ; and noAv
1 am so tired with a long attendance at (luildhall yesterday
and to-day, being siibpronaed, with Sir H. Davy, ■Mr. Brande,
Phillips, Aikin, and others, to give chemical information on a
trial (which, however, did not come off), that 1 scarcely know
what I say.
Shortly afterwards Davy again went abroad, but
P^iraday remained in England. From Rome Davy
Avrote a note, the concluding sentence of which shows
how Faraday was advancing in his esteem. —
Kome : October, 1818.
Mr. Hatchett's letter contained praises of you wliich were
very gratifying to ine ; for, l)elieve me, there is no one more
interested in your success and welfare than your sincere well-
wisher and friend,
H. Davy.
BEGINS ORIGINAL TtESEAUGHES. 45
Li the next year Davy wrote again, suggesting to
Faraday that he might possibly be asked to come to
Naples as a skilled chemist to assist in the unrolling
of the Herculaneum manuscripts. In May he wrote
again, from Florence : —
It gives me great plea.^ure to hear that you are comfortable
at the Royal Institution, and I trust that you will not only do
something good and honourable for yourself, but likewise for
science.
I am, dear Mr, Faraday, always your sincere friend and
well-wisher,
H. Davy.
The wish that Davy expressed that Farada}' might
^' do soniething" for himself and likewise for science
was destined soon to come to fulfilment. But in
the case of one who had worked so closely and had
been so intimately associated as an assistant, it imist
necessarily be no easy matter always to draw a
distinction between the work of the master and that
of the assistant. Ideas suggested by one might easily
have occurred to the other, when their thoughts had
so long been directed to the same ends. And so it
proved.
Reference to Chapter III. will show that alread}^,
beginning in 1816 with a simple anal3'sis of canstic
lime for Sir Humphry Davy, Faraday had become an
active worker in the domain of original research. The
fascination of the quest of the unknown was already
upon him. While working with and for Davy on the
properties of flame and its non-transmission through
iron gauze^ in the investigation of the safety lamp,
other problems of a kindred nature had arisen. One
46 MiriIAi:i. FARAIJAY.
of tliGso, relating to the tlow of gases through capillary
tubes, Faraday had attacked by himself in 1 817. The
subject formed one of the six original papers which
he published that year. In the next two years he
contributed in all no fewer than tliirty-seven papers
or notes to the Qicarterlij Joiir'aal of Science. In
ISIO began a long research on steel which lasted over
the year 1820. He had already given evidence of
that dislike of lialf-truths, that aversion for "doubtful
knowledge " which marked him so strongly. He had
exposed, with ipiiet but unsparing success, the empti-
ness of the claim made by an Austrian chemist to
have discovered a new metal, " Sirium," by the simple
device of analysing out from the mass all the con-
stituents of known sorts, leaving Ijehind — nothing.
And now, Faraday being twenty-nine years of age,
a new and all-important episode in his life occurred.
Amongst the members of the little congregation
which met on Sundays at Paul's Alley, Red Cross
Street, was a Mr. Barnard, a working silversmith of
Paternoster Row, an elder in the Sandemanian body.
Ho had t W(j sons, Ed ward Barnard , a fri end of
Faraday's, and George, who became a well-known
water-colour artist ; and three daughters ; one who was
already at this time married; Sarah, now twenty-one
years of age ; and Jane, Avho was still younger.
Edward had seen in Faraday's note-book those boyish
tirades against falling in love, and had- told his sister
Sarah of them. Nevertheless, in spite of all such
misogynistic fancies, Faraday woke up one day to
find that the large-eyed, elear-browed girl had grown
to a place in his heart that he had thought barred
HE FALLS IN LO\'E. -i '
against the assaults of love. She asked him on one
occasion to show her the rhymes against love in his
note-book. In repl}^ he sent her the hitherto un-
published poem : —
11. L
Oct. nth, 1819.
You ask'd me last night for the lines \vhich I penn'd,
When, exulting in ignorance, tempted by pride,
I dared torpid hearts and cold breasts to commend,
And ati'ection's kind pow'r and soft joys to deride.
If you urge it I cannot refuse your request :
Though to grant it will punish severely my crime :
But my fault I repent, and my errors detest ;
And I hoped to have shown ni}' conversion in time.
hemember, our laws in their mercy decide
That no culprit be forced to give proof of his deed :
They protect him though fall'n, his failings they hide,
And enable the wretch from his crimes to receed (.s/c).
The principle's noble I I need not urge long
Its adoption ; then turn from a judge to a friend.
Do not ask for the proof that I once acted wrong, """<
But direct me and guide me the way to amend.
M. F.
What other previous passages bet\veen them are hinted
at in the letter "which he sent her, is unknown ; but
on July 5, 1S20, he Avrote : —
Koyal Institution.
You know nie as well or better than I do myself. Y'ou
know my former prejudices, and my present thoughts — you
know my weaknesses, my vanity, my whole mind ; you have
converted me from one erroneous way, let me hi^ipe you will
attempt to correct what others are wrong.
Again and again I attempt to say what 1 feel, but I cannot.
48 MK'TIAEL KAIJAPAV.
Let iiiL', howevei-, claim not to bo the selfish Iteing tluit
wishes to l^end your aHections for his own sake only. In
whatever way I can best minister to your ha])piness eitlier l)y
assiduity or l)y absence, it shall 1)0 i\nue. Do not injure me
by withdrawing your friendsliip, or punish nn; b^- aiming to
be more than a friend by making me less ; and if you cannot
grant me more, leave me what I possess, but hear me.
Sarah Barnard sliowcd the letter to lier father.
She was 3'ounL^\ and feared to aecept her lover. All
her father would say by Avay of counsel was that bjve
made philosophers say many foolish thint^^s. The
intensity of Faraday's passion proved for the time a.
bar to his advance. Fearing lest she should be unable
to return it with equal force, Miss Barnard shrank
from replying. To postpone an immediate decision,
she went away with her sister, Mrs. Reid, to Ramsgate.
Faraday followed to press his suit, and after several
liappy days in her company, varied with country
walks and a run over to Dover, he was able to say :
"Not a moment's alloy of this evening's happiness
occurred. Everything was delightful to the last
moment of my stay with my companion, because she
was so."
Of the many letters that Faraday Avrote to his
future wife a number have been preserved. They arc
manly, simple, full of quiet affection, but absolutely
free from gush or forced sentiment of any kind.
p]xtracts from several of them are printed by ]>ence
Jones. One of these, written early in 1821, runs as
follows : —
I tied np the enclosed key with my books last night,
and make haste to return it lest its absence should occasion
A HAPI'V MAUKIAUE. 40
confusion. If it haw, it Avill perhaps remind you of the disorder
I nRi:st be ill here also for the want of a key— I mean the one to
my heart. However, I know where my key is, and hope soon
to have it here, and then the Institution will be all right again.
Let no one oppose my gaining possession of it Avhen unavoid-
able obstacles are removed.
Ever, my dear girl, one who is ]ierfectly yours,
M. Fakaday.
Faraday obtained leave of the managers to bring
his wife to live in his rooms at the Institution ; and
in May, 1821, his position Avas changed froiu that of
lecture assistant to that of superintendent of the
house and laboratory. In these changes Sir Humj^hry
Davy gave him w'illing assistance. But his salary
reniained £100 a year.
Olistacles being now removed, Faraday and Miss
Bat^nard were married on June 12. Few persons were
asked to the wedding, for Faraday Avished it to be
"just like any other day." " There Avill," he Avrote,
" be no bustle, no noise, no hurry. ... it is in the
heart that we expect and look for pleasure."
His marriage, though childless, Avas extremely
^^^^PP3'- ^^^'^- Faraday proved to be exactly the true
helpmeet for his need : and he loved her to the end
of his life Avith a chivalrous devotion Avhich has
become almost a proverb. Little indications of his
attachment crop up in miexpected places in bis
subsequent career ; but as Avith his religious vicAvs so
Avith his domestic affairs, he never obtruded then
upon others, nor yet shrank from mentioning them
"when there was cause. Tyndall, in alter years, made
the intensity of Faraday's attachment to his Avife the
E
50 MICHEAL FAltADAV.
subject of a strikinG: simile : " Never, I believe, existed
a manlier, purer, steadier love. Like a burnmg
diamond, it continued to shed, for six and forty years,
its white and smokeless glow."
In his diploma-book, now in possession ot the
Royal Society, in which he carefully preserved all the
certificates, awards, and honours bestvowed upon him
by academies and universities, there may be found on
a slip inserted in the volume this entry ; —
25tli January, 1847.
Amongst these records and events, I here insert the date of
one which, as a source of honour and hapi)ines8, far exceeds
the rest. We were married on June 12, 1821.
M. Faraday.
And two yea>rs later, in the autobiographical notes
he Avrote : —
On June 12, 1821, he married— an event which more than
any other contributed to his earthly happiness and healtlitul
state of mind. The union has continued for twenty-eiglit
years, and has nowise changed, except in the depth and strength
of its character.
^\'hen near the close of his life, he presented to
the Eoyal Institution the bookcase with the volumes
of notes of Davy's lectures and of books bound by
himself, the inscription recorded that they were the
^nft of " Michael avxi. Sarah Faraday-."
Every Saturday evening he used to take his wife
to her father's house at Paternoster Plow, so that on
Simday they should be nearer to the chapel at Paul's
Alley. And in after years, when he was away on
scientific work, visiting lighthouses, or attendino-
FIRST ELECTRICAL DISC-*.)VERV. -51
meetiii^^s ot* the Britif^h Association, he alwavs tried
to return tor the Sunday.
A let':er tL'om Licbig in lS4-lr {see p. 225) gives one
of the very few gKnipses of conteuiporary date of the
impression made by Mrs. Faraday upon others.
One month alter his marriage Faraday made his
profession of faith before the Sandemanian church, to
Avhich his wife ah'eady belonged, and was admitted a
member. To his rehgious views, and his rehitions to
the body he thus formally joined, reference will be
found later.
Faraday now settled down to a routine life oi
scientitic work. His professicaial reputation was
rising, and his services as analyst were being sought
atter. But in the midst of this he was pursuing
invest igatii:>ns on his own account. In the late
summer o( this year he made the discovery oi the
electro-magnetic rotations desci'ibed in Chapter IIL —
his hrst important piece of original research — and
had in consequence a serious misunderstanding with
I'r. WoUaston. On September ord. working' with
George Barnard in the laboratory, he saw the electric
wire for the lirst time revolve around the pole of the
magnet. Paibbing his hands as he danced around the
table with beaming face, he exclaimed : " There they
go ! there they go '. we have succeeded at la^t."" Then
he gleefully proposed that they should wind up
the day by going to one of the theatres. Which
should it be f '' Oh. to Astley's. to see the horses."
And to Astley's they went. (Jn Christmas T»ay he
called his young Avife to see something new : an electric
couductino'-wire revolvinir under the inliuence of the
52 MICHAEL FARADAY.
iiiagnetisui of the earth alone. He also read two
chemical papers at the Royal Society, announcing
new discoveries ; one of them in conjunction with his
friend Phillips. In July, lcS22, he took his wife and
her mother to Rams<]fate, whilst ho went off with
Phillips to Swansea to try a new process in Vivian's
copper -works. During this enforced parting, Faraday
wrote his wife three letters from which the folloAving
are extracts : —
■ (July 21, 1822).
I })erceive that if I give way to my thoughts, I shall write
you a mere love-letter, jast as usual, with not a particle of
news in it : to prevent which I will constrain myself to a
narrative of what has happened since I left you up to the
present time, and then intkilge my alfection.
^'esterday was a day of events— little, but pleasant. I
went in the morning to the Institution, and in the course of
the day analysed the water, and sent an account of it to Mr.
Hatchett. Mr. Fisher I did not see. Mr. Lawrence called in,
and Vtehaved with his usual generosity. He had called in the
early part of the Aveek, and, finding that I should be at the
Institution on Saturday only, came up, as I have already said,
and insisted on my accepting two ten-pound bank-notes for
the information he professed to have ol)tained from me at
various times. Is not this handsome? The money, as you
know, could not have been at any time more acceptable ; and
I cannot see any reason, my dear love, why you and I should
not regard it as another proof, among many, that our trust
should without a moment's reserve be freely reposed on Him
who provideth all things for His peofile. Ha\e we not many
times been re))roached, by tucli mercies as these, for our caring
after food iind raiment and the things of this world ?
On coming home in the evening, /.c, coming to Paternoster
Ro-\v home, I learned that ]\Ir. Phillips had seen C, and had
told her we siuiuhl nut leave London until Monday evenin<^.
'' A MERK LOVK-J.ETTEK." 53
So I shall ]iave to-morrow to get things ready in, and I shall
have enough to do. I fancy we are going to a large mansion
and into high company, .so I must take more clothes. Having
the £20, I am hecorae bold
And now, how do my dear wife and mother do ? Are you
conifortable *? are you happy? are the lodgings convenient, and
Mrs. O. obliging? Has the phice done you good I Js tlic
weather fine? Tell me all things as soon as you can. I think
if you write directly you get this it will be best, but let it be u
long letter. I do not know when I wished so nuich foi' a long
letter as 1 do from you now. You will get this on Tuesday,
and any letter from you to nie cannot reach Swansea before
Thursday or Friday— a sad long time to wait. Direct t(j me,
Post Otfice, Swansea ; or perhaps better, to me at — Vivian
Esq., Marino, near Swansea, South Wales
And now, my dear girl, I must set business aside. I am
tired of the dull detail of things, and want to talk of love to
you; and surely there can be no circumstances under which 1
can have more right. The theme was a cheerful and delightful
one before we were married, but it is doubly so now. I now
can speak, not of my own heart only, but of both our hearts.
I now speak, not with any doubt of the state of your thoughts,
but with the fullest conviction that they answer to my own.
All that I can now say warm and animated to you, 1 know
that you would say to me again. The excess of pleasure wbicli
I feel in knowing you mine is doubled by the cunscionsness
that you feel equal joy in knowing me yours.
Marino : Sunday, July 28, 1822.
My dearly beloved Wife,— I have just read your letter
again, preparatory to my writing to you, that my thoughts
might be still more elevated and quickened than before. 1
could almost rejoice at niy absence from you, if it were only
that it has produced such an earnest and warm mark of
affection from you as that letter. Tears of joy and delight fell
from my eyes on its perusal. I think it was last Sunday
evening, about this time, that I wrote to you from London ;
and I again resort to this affectionate cnnversation with ynn,
54 MICHAEL FAltADAV.
to tell you Avhat Las happened since the letter which I got
franked from this place to you on Thursday I believe.
We have been working very hard here at the copper works,
and with some success. Our days have gone on just as before.
A walk before breakfast ; then breakfast ; then to the works
till four or five t)'clock, and then home to dress, and dinner.
After dinner, tea and conversation. I have felt doubly at a
loss to-day, being absent from both the meeting and you.
When away from London before, I liave had you with me, and
we could read and talk and walk ; to-day 1 have had no one to
fill your place, so I will tell you how I have done. There are
so many here, and their dinner so late and long, that I made
up my mind to avoid it, though, if possible, without appearmg
singular. So, having remained in my room till breakfast time,
we all breakfasted together, and soon after j\[r. Phillips and
myself took a Avalk out to the Mumbles Point, at the extremity
of this side of the ba3^ There we sat down to admire the
beautiful scenery around us, and, after we had viewed it long
enough, returned slowly home. We stopped at a little village
in our way, called Oystermouth, and dined at a small, neat,
homely house about one o'clock. We then came back to
Marino, and after a little while again went out — Mr. Phillips
to a relation in the town, and myself for a walk on the sands
and the edge of the bay. I took tea in a little cottage, and,
returning home about seven o'clock, found them engaged at
dinner, so came up to my own room, and shall not see them
again to-night. I went down for a light just now, and heard
them playing some sacred music in the drawing-room; they
have all been to church to-day, and are what are called regular
people.
The trial at Hereford is put off for the present, but yet we
shall not be able to be in town before the end of this week.
Though I long to see you, I do not know when it will be ; but
this I know, that I am getting daily more anxious about you.
Mr. Phillips wrote home to Mrs. Phillips from here even before
I did— /.^. last Wednesday. This morning he received a letter
FROM HUSJiAND T(J WIPE. 55
from Mrs. Phillips (who i« very well) desiring him to a.sk me
for a copy of one of my letters to you, that he may learn to
write love-lettei'S of sufficient length. He laughs at the scold-
ing, and says that it does not hurt at a distance
It seem.s to lue so long since I left you that there must li;ive
been time for a great many things to have happened. I
expect to see you with such joyAvhen I come home that I shall
hardly know what to do with myself. I hope ytiu will be well
and blooming, and animated and hap]»y, when you see me. I
do not know how we shall contrive to get away from here.
We certainly slmll not have concluded before Thursday even-
ing, but T think we shall endeavour earnestly to leave this
place on Friday night, in which case we shall get home late on
Saturday night. If Ave cannot do that, as I should not like to
be travelling all day on Sunday, we shall probably not leave
until Sunday night ; but I think the first plan will be adopted,
and that you w^ill not have time to answer this letter. I expect,
nevertheless, an ani^wcr to my last letter— /.f. I expect tliat
ray dear wife will think of me again. Expect here means
nothing more than I trust and have a full confidence that it
Avill be so. My kind girl is so allectionate that she would not
think a dozen letters too niuch for me if there were time to
send them, which I am glad there is not.
Give my love to our mothers as earnestly lis you would
your own, and also to Charlotte or John, or any such one that
you may have Avith you, I have not Avritten to Paternoster
Row yet, but I am going to write now, so that I may be
permitted to finish this letter here. I do not feel <iuite sure,
indeed, that the permission to leave off is not as necessary
from my own heart as from yours.
With the utmost affection— AA-ith perhaps too much— I am,
my dear Avife, my Sarah, your devoted husband,
]\I. Faraday.
Faraday's next scientific success was tire liquefac-
tion of chlorine (see Chapter III., p. 93). This dis-
covery, which created much interest in the scientific
56 MHJHAEJ. FAUADAV.
world, was the occasion of a serious trouble with Sir
Humphry Davy ; for doubtless Davy was annoyed
that he had left such a simple experiment to a mere
assistant. Writing on the matter years after, Faraday
said : —
When my paper was written, it was, according to a custom
consequent upon our relative positions, submitted to Sir H.
Davy (as were all my papers for the "Philosophical Transac-
tions" up to a much later period), and he altered it as Le
thought fit. This practice was one of great kindness to me,
for various grammatical mistakes and awkward expressions
were from time to time thus removed, which might else have
remained.
In point of fact, Davy on this occasion added a
note (which was duly printed) saying precisely how
far he had any share in suggesting the experiment,
bat in no wise traversing any of Faraday's claims.
Although he thus acted generously to the latter, there
can be no question that he began to be seriously
jealous of Faraday's rising fame. The matter was the
more serious because sonie who did not have a nice
appreciation of the circumstances chose to rake up a
chartre which had been raised two years before as.i'ainst
Faraday by some of Dr. WoUaston's friends — in par-
ticular by Dr. AVarburton — about the discovery of the
electro-rnagnetic rotations, a charge which Faraday's
straightforward action and WoUaston's frank satis-
faction ought to have dissipated for ever. And all
this was doubly aggravating because Faraday was
now expecting to be proposed as a candidate for the
Fellowship of the Royal Society, of which Sir Humphry
was President.
PROP(JSED FOR THE FELLOWSHIP. 5i
At that time, as now, the proposal paper or
" certiiicate " of a candidate for election must be
presented, signed by a number of influential Fellows.
Faraday's friend Phillips took in hand the pleasant
task of drawing up this certiiicate and of collecting
the necessary signatures. The rule then was that the
(certificate so presented must be read out at ten
successive meetings of the Society ; after Avhich a
ballot took place. Faraday's certificate bears twenty-
nine names. The ver}' first is that of Wollaston, and
it is followed by those of Children, Babington, Sir John
lierschel, Babbage, Phillips, Roget, and Sir James
South.
On the 5th of May, 1S2:>, Faraday wrote to
Philhps :—
A thousand thanks to you for your kindness — I am delighted
with the names — Mr. Brande had told me of it before I gut
your note and tlionght it impossible to be better. I suppose
you will not be in Grusvenor Street this Evening, so I will ])ut
this in the post.
Our P>est remembrances to Mrs. Phillips.
^^our^ Ever,
M. Faraday.
The certiiicate was read for the first time on
May 1st. The absence of the names of Davy and
Brande is accounted for by the one being President
and the other Secretary. Bence Jones gives the
foHowing account of what followed: —
Tliat Sir H. Davy actively opi)Osed Faraday's election is no
less certain than it is sad.
^lany years ago, Faraday gave a friend the fnllnwing facts,
58 MICHAEL FARAIXAY.
which were ^vritten down iiiiinediately : — " Sir H. Davy told
me I must take down my certificate. I replied that I had not
put it up ; that I couhl not take it down, as it was put up by
my proposers. He then said I must get my iiroposers to take
it down. I answered that 1 knew they would not do so.
TIkmi ]ie said, 1 as PrL-sident will take it down. I replied that
I was sure Sir H. Davy would do what he thought was for the
:j,ood of the Koyal Society.'
Faraday also said that one of his proposers told him that
Sir H. Davy had walked for an hour round the courtyard of
Somerset House, arguing that Faraday ought not to be elected.
This was probably about May .3".
Faruda}' also made the following notes on the
circumstance of the charge made by Wollaston's
friends :—
1823. In rd'.ition tu Dooiia oj'posituyji to imj election at the
Eoi/al Society.
Sir H. Davy angry, May 3o.
Phillips' report through Mr. Children, June o.
^Ir. Warburton called hrst time, June 5 (evening).
1 culled on Dr. AVollaston, and he not in titwn, June 9.
I called on Dr. Wollaston, and saw him, June 14.
I called at Sir H. Davy's, and he called on me, June 17.
On July S Dr. Warburton wrote that he was
satisfied with Farada3''s exphination, and added that
he would tell his friends that " my objections to you
as a Fellow are and ou^dit to be withdraAvn, and that
I now w^ish to forw^ard your election."
Bence Jones adds : —
On June i29, Sir H. Davy ends a note, "I am, dear Faraday,
very sincerely your well wisher and friend.'' So that outwardly
the storm rapidly passed away ; and when the ballot was
taken, after the certificate had been read at ten meetings, there
was only one black ball.
KELLOWSHLL' AND MAGNANIMITY. 50
The election took place January 8, 1824.
Of this unfortunate misunderstanding-,"^'" Davy's
biographer, Dr. Thorpe, writes :—
The jealousy tlius manifested by Davy is one of the most
])itiful facts in his history. It was a sign of that moral weak-
ness which Avas at the bottom of much of his unpopularit}',
and which revealed itself in various ways as his physical
strengtli decayed." . . . ■
Faraday allowed himself in after days no shade of
resentment against Davy; though he confessed rather
sadly that after his election as F.B.S. his relations
with his former master were never the same as before.
If anyone recurred to the old scandal, he "would hre
with indignation. Dumas in his " Eloge Historiquo "
has given the following anecdote: —
Fai aday never forgot Avhat he owed to Davy. Visiting him
at the family lunch, twenty years after the death of the latter,
he noticed evidently that I responded with some coolness to
the jjraises which the recollection of Davy's great discoveries
had evoked from him. He made no comment. But, after the
meal, he simply took me down to the library of the Iloyal
Institution, and stopping before the t»ortrait of Davy he said :
" He Avas a great man, Avasrft he?" Then, turning round, lie
added, "It was heref that he spoke to me for the first time."
I boAved. We Avent down to the laboratory. Faraday took
* A Avritor in the Quarierlij Jonrncd of Science for 1868, p. 50, f-;n s :
" Wo have leason to know that Davy Avas shghtly annoyed that the
certificate proposing Faraday foi' election should have originated with
liichard Phillips, and that he should not have heen consulted before
that gentleman was alloAved to take the matter in hand." This is
absurd, because the President was by long-standing etiquette deliaircd
fi'oni signing Ihe certificates of any but foreign members, as the
certificate book (if the Royul Socipty attests.
t Seep. I'l.
(iO MICHAf:L FAKADAV.
out a note-book, (jptued it and pointed out with bis finger the
■words written by Davy, at the very moment when l-y means
of the battery he had just decomposed potasli, and had seen
the first globule of potassium ever isolated Ijythe hand of man.
Davy had traced with a feverish liand a circle which separates
them from the rest of the fiage : the words, '•' Capital Experi-
ment,'' which he wrote belnw, cnnnot be read without emotion
by any true chemist. I confessed myself conquered, and this
tmie, without hesitating longer, L jnined in the admiration <jf
my good friend.
■ ])r. Thorpo in his life of Uavy adds : —
.... To the end of his days he [Faraday] regarded Davy
as his true master, preserving to the last, in spite of his know-
ledire of the moral frailties of Davy's nature, the respect and
even reverence which is to be seen in his early lecture notes
and in his letters to his friend Abbott.
Ill 1S28 the Athen.-i-niii (Jliilj was started liy J.
Wilson C'roker, Sir H. Davy, Sir T. Lawrence, Sir F.
Chantrev, and otliers, as a resort for literary and
scientitic men. I^araday was made Club Secretar}' ;
but he found the duties totally uncon,Grenial, and in
1 s2-lr resigTied the post to his friend Mai^rath.
Faradav was advanced in 1825 to the position of
Director of the Laboratory of the Royal Institution,
FJrande remaining Professor of Chemistry. One of
the first acts of the new Director was to hold evening
meetings of the members in the laboratorv, wdien
experiments were shown and some demonstration was
o-iven. There were three or four of these informal
gatherings that year. In the next year these Friday
evening meetings were held more systematical!}'.
There were seA-enteen durin'j- the season, at six of
FEES FOR PKOFESSIOXAL WOKK. 61
which Farada}^ gave discourses (sef' p. 100). In 1827
there were nineteen, of which he dehvored three.
By this time the gatherings Avere held in the theatre
as at present, save that hidies Avere only admitted at
that date, and for many 3'ears, to the upper gallery.
He also originated the Christmas lectures to juveniles,
while eontinuino- to 2'ive reo'ular courses of morning"
lectures, as his predecessors Young and Davy had
done. His activity for the Royal Institution was
incessant.
Down to the year 1880 Faraday continued to
undertake, at professional fees, chemical analyses and
expert work in the law-courts, and thereb}^ added
considerabl}' to the very slender emolument of his
position; but, finding this Avork to make increasing
flemands on his time, Avhich he could ill spare from
the absorbing pursuit of original researches, he
decided to abandon a practice which Avoidd liaA'e
nmde him rich, and Avithdrew irom expert practice.
The foUoAving letter to Phillips Avas Avritten only a few
weeks before this determination: —
[J/. Fanuhnj to Rirhard PJullii>:<.'\
hoyal Iiistitutinn,
June -21, 1831.
My dear Phillips, — 1 liaA^e been tryiiiA' liard to get time
enough to write to you Iiy post to-niglit, l.tut without success ;
the Vtell has riuig, and I am too Lite. Hu^ve^■e^, 1 am resolved
to be ready to-morrow. \Ve liave l)ee]i Aery anxious and
rather embarrassed in our minds about your anxiety to know
how things Avere i)roceeding, and uncertain Avhother reference
to them woukl be pleasant, and that has heen the cause Avhy I
h'J. MICHAEL FARADAY.
have not written to yon, for I did wm know whu character
your connexion with Badanis had. I was a little the more
embarrassed because of my acquaintance with Mr. Rictard
and hi> family, and, of course with his brother-in-law. Dr.
Urchell, of whom I have made numerous enquiries to know
what Mr. Kiekard intended doing at Birmingham. He
(expressed a) hope it would be nothing unpleasant tn you, but
was m>t sure. Our only bit of comfort in the matter was on
hearing from Daniell about you a little : he was here to-day.
and glad to hear of you through me. But now that I may
write, let me say that Mrs. Faraday has been very anxious
with myself, and begs me earnestly t-? remember her to Mrs.
Phillips. We have often wished we could have had you here
for an hour or two. to break off what we supposed might be
the ti-ain of thoughts at home.
With regard to the five guineas, do not think of it for a
moment. Whilst I supposed a mercantile concern wanted my
opinion ivv its own interested uses, I saw no reason why it
should not pay me : but it is alt^jgether another matter when
it becomes your on'air. I do not think you would have
wished me to pay you five guineas for anything you might
have done personally for me. " Dog don't eat dog," as Sir E.
Home said t'"> me in a similar case. The affair is settled.
I have no doubt I >hall be amu-^ed and, as you speak of
new facts, instructed by your letter to Dr. Eeid, as I am by all
your letters. Daniell says he thinks you are breaking a tly
upon the wheel. You know I consider you as the Prince of
Chemical critics.
Pearsall has been working, as you know, on i*ed man-
ganese solutions. He has not proved, but he makes out a
.strong case for the opinion, that they owe their colour and
other properties to manganesic acid. This paper will be in
the next numV»er of the Journal.
With regard to the gramme, wine-pint, etc.. etc., in the
manipulation I had great trouble about them, for I could find
no agreement, and at last resolved to take certain conclusions
from Capt. Katers paper and the Act of Parliament, and
calculate the rest. I think I took the data at i»age 67
SACRIFICES Foil SCIEXi'i:. Ho
]iar;i,i;rapli lU). ns the data, but am not sure, and cannot ,£:o
over them again.
My memory gets worse and worse ihiily. I will not,
therefore, say 1 have not received yonr JMi.u-macopa-ia — that
of 1824 is what I have at hand and use. I am nut aware of
any other. I have sent a paper to the If. .S., but not chemical.
It is on sound, etc., etc. If they pri]it it. of course you will
have a copy in due time.
I am, my dear Philliits,
Most faithfully and sincerely yours,
'M. Faraday.
Is it right to ask what has berome of Badams ''. I sujipose
he is. of coarse, a defaulter at the K. S.
This sacrifice for science Avas not small. He had
made £1,000 in LS30 out of these professional
occupations, and in 1S3I would have made more but
for his own decision. In 1S32 some Excise work that
he had retained brought him in £155 9s. : but in no
suftsequent year did it bring in so much. He might
easily have made £5,000 a year had he chosen to
cultivate the professional connection thus formed :
and as he continued, with little intermission, in
activity till 18li0, he might have died a wealthy man.
But he chose otherwise ; and his first reward came in
the au t umn of 183 1 , in t he great discovery of
magneto-electric currents — the principle upon which
all our modern dynamos and transformers are based,
the foimdation of all the electric lighting and electric
transmission of power. From this work he went on
to a research on the identity of all the kinds of
electricity, until then supposed to be of separate sorts,
and from this to electro-chemical work of the very
04 :\11LHAEL FAKAOAV.
luGcliest value. <Jf all these investigations some
account will be found in the chapters which
follow.
But the innnense body of patient scientific work
thus done for the love of science was not accom-
plished Avithout sacrifices of a more than pecuniary
kind. He withdrew more and more from society,
declined to dine in company, ceased to give dinners,
withdrew from all social and philanthropic organisa-
tions ; even withdreAv froui taking any part in the
management of ari}' of the learned societies. The
British Association for the Advancement of Science
was started in 1831. Faraday took no part in that
movemerit, and did not attend the iiiaugural meeting
at York. The next year, however, he attended the
second meeting of that body at Oxford. Here he
" had the pleasure" — it is his own phrase — of making
an experiment on the great ma.gnet in the University
museum, drawing a spark by induction in a coil of
wire. This was a coil 220 feet long, wound on a
hollow cylinder of pasteboard, which had been used
in the classical experiments of the preceding year.
He also showed that the induced currents could heat
a thin wire connected to the tenninals of this coil.
These experiments, which were ujade in conjunction
with Mr. (afterwards Sir AVilliam Snowj Harris, Pro-
fessor I'aniell. and Mr. Duncan, seem to have excited
great attention at the time. The theologians of
Oxford appear to have been rnightil}' distressed both
Ijy the success of the spark experiment and by the
welcome shown by the University to the representa-
tives of science. The following passage from Pusey's
THE HODGE-PODOE OF PHILOSOPPTERS. 05
life * reveals the rampant clericalism which then and
for a score of years sought to put back the clock oi
civilisation.
Duriri,i; the Long Vacation of 1832 Pusey had plenty of
■work on hand. The British Association had held its first
meeting in Oxford during the month of June, and on the 21st
the honorary degree of D.CL. Avas bestowed on four of its
distinguished members : Brewster, Faraday, Brown, and
Dalton. Keble, wlio was now Professor *A' Poetry, was angry
at the "tt'inper and tone of the Oxford doctors"; they had
''truckled sadly to the spirit of the times'' in receiving "the
hodge-podge of philosophers " as they did. Dr. L. Carpenter
had assured Dr. Macbride that "the University had prolonged
her existence for a hundred years by the kind reception he
and his fellows had received."
It is not wuthout significance, perhaps, that all the
four men thus contemptuously labelled by Keble as
the " hodge-podge of philosophers " were Dissenters.
Brewster and Brown (the great botanist and dis-
coverer of the " Brownian " motion of particles)
belonged to the Presbyterian Church of Scotland,
Dalton was a Member of the Society of Friends, and
P'araday a Sandemanian. Newman appears to have
been equally discomposed by the circumstance, for he
got his friend Mr. Rose to write an article — a long
and weary diatribe — against the British Association,
which he inserted in the British Critic for 1839.
Its slanders, assumptions, suppressions, and sugges-
tions are in a very unworthy temper.
Faraday's devotion to the Royal Institution and
its operations was marvellous. He had already
* Liddon'.s '^ Life of £. B. Pusey " (lS9:i), p. 219.
F
*i(i MICHAEL FARADAY.
abandoned ontside professional Avork. From 1S3S he
refused to see any callers except three times a v^eek.
His extreme desire was to give himself uninterrupt-
edly to research. His friend A. de la Rive says : —
Every morning Faraday went into Lis laboratory as the
man of business goes to his office, and then tried by experi-
ment the truth of the ideas \Yhich he had conceived overnight,
as ready to give them up if experiment said jio a-s to follow
out the consequences with rigorous logic if experiment an-
swered i/tS.
He had in 1S27 declined the appointment of
Professor ot Lhennstry in the University (afterwards
called University College) of London, giving as his
reason the interests of the Fioyal Institution. He
wrote : —
I think it a matter of duty and gratitude on my part to do
what I can for the good of the Fioyal Institution in the
present attempt to establish it tirmly. The Institution has
been a source of knowledge and pleasure to me for the last
fourteen years : and though it does not pay me in salary what
I noir strive to do for it, yet I possess the kind feelings and
goodwill of its authorities and members, and all the privileges
it can grant or I require ; and, moreover, I remember the
protection it has afforded me during the past years of my
scientific lite. These circumstances, with the thorough con-
viction that it i.-^ a useful and valuable establishment, and the
strong hopes that exertions will be followed with success, have
decided me in giving at least two years more to it, in the
belief that after that time it will proceed well, into whatever
hands it may pass.
In IS29. however, he was asked to become lecturer
on chemistry at the Royal Academy at Woolwich. As
this involved onl}' twent}' lectures a year he agreed.
TRINITY HOUSK APPOIXTMEXT. 67
the salary being fixed at £200 a year. These lectures
were continued until 1849.
In 183(3 the whole course of his scientific work
was changed by his appointment as scientific adviser
to Trinity House, the body which has official charge
of the lighthouse service in Great Britain. To the
Deputy- master he wrote : —
I consider your letter to me as a great compHment, and
should view the appointment at the Trinity House, which yon
projiose, in the same light ; but I may not accept even honours
without due consideration.
In the first place, my time is of great value to me ; and
if the appointment you speak of involved anything like
jieriodical routine attendances, I do not think I could accept it.
But if it meant that in consultation, in the examination of
proposed plans and exjieriments, in trials, etc., made as my
convenience would allow, and with an honest sense of a duty
to be performed, then I think it wonld consist with niy present
engagements. You have left the title and the sum in pencil.
These I look at mainly as regards the character of the appoint-
ment ; you will believe me to be sincere in this when you
remember my indifference to your proposition as a matter
of interest, though not as a matter of kijulness.
In consequence of the goodwill and confidence of all around
me, I can at any moment convert my time into money, but I
do not re(pure more of the latter than is sufficient for neces-
sary puri)0ses. The siun, therefore, of £200 is quite enough in
itself, but not if it is to be the indicator of the character of
the appointment ; but I think you do not view it so, and that
you and I understand each other in that respect ; and your
letter confirms me in that opinion. The jiosition which I
presume you would wish me to hold is analogous to that
of a standing counsel.
As to the title, it might be what you pleased almost.
Chemical adviser is too narrow, for you would find me ven-
turing into parts of the philosophy of light not chemical.
68 MICHAEL FARADAY
Scientific adviser you may think too broad (or in me too
presumptaous) ; and so it would be, if by it was understood
all science.
He held the post ot scientific adviser for nearly
thirty years. The records of his work are to be
found in nineteen large portfolios full of manuscripts,
all indexed with that minute and scrupulous atten-
tion to order and method which characterised all
his work.
He also held nominally the post of scientific
adviser to the Admiralty, at a salary of £200 a year.
But this salary he never drew. Once the officials of
the Admiralty requested his opinion upon a printed
advertising pamphlet of somebody's patent disinfect-
ing powder and anti-miasma lamp. Faraday returned
it, with a quietly indignant protest that it was not
such a document as he could be expected to give an
opinion upon.
Faraday's hope, expressed in 1827, that in two
years the Royal Institution might be restored to a
financially sound position, was not realised. He
worked with the most scrupulous economj^, noting
down every detail of expenditure even in farthings.
" We were living on the parings of our own skin,"
he once told the managers. In 1832 the financial
question became acute. At the end of that year a
committee of investigation reported as follows ; —
The Committee are certainly of opinion that no reduction
can be made in Mr. Faraday's salary — £100 per annum, house,
coals, and candles ; and beg to express their regret that the
circumstances of the Institution are not such as to justify
their proposing such an increase of it as the variety of duties
A HUNDRED A YEAR, AND TWO ROOMS. 69
which Mr. Faraday has to perform, and tlie zeal and ability
with which he performs them, appear to merit.
A hundred a year, the use of two rooms, and
coals ! Such was the stipend of the man who had
just before been made D.C.L. of Oxford, and had re-
ceived from the Royal Society the highest award it
can bestow — the Copley Medal ! True, he made £200
by the AVoolwich lectures; but he had a wife to main-
tain, his aged mother was entirely dependent upon
him, and there w^ere many calls upon his private
exercise of charit}^
About the year 1835 it w^as the intention of Sir
Robert Peel to confer upon hijn a pension i'rom the
Civil List, but he went out of office before this could
be arranged, and Lord Melbourne became Prime
Minister. Sir James South had in March written
to Lord Ashley, afterAvards the well-known Earl ot
Shaftesbury, asking him to place a little historiette
of Faraday in Sir Robert Peel's hands. The said
historiette* contained an account of Faraday's early
career and a description of the electrical machine
Avhich he had constructed as a lad. " Now that his
pecuniary circumstances," it Avent on, " were im
proved, he sent his younger sister to boarding-school,
but to enable him to defray the expense, to deprive
himself of dinner every other day was absolutely in-
dispensable." Peel expressed to Ashley lively regret
at not having received the historiette earlier when he
was still in office. To Ashley, later, he wrote the
following hitherto unpublished letter : —
* For this information and many particulars of this transaction I
am indehted to Dr. J. H. Gladstone, F.R.S.
70 MICHAEL FAEADAY.
])rayton Manor,
May 3, 1835.
My Dear Ashley,— You do nie but justice in enter-
taining the belief that had I remained in oflice one of my
earliest recommendations to his ^Fajesty Avould have been to
grant a pension to Mr. Faraday, on the same jirinciples pre-
cisely upon "which one was granted to Mr. Airy. If there
had been the means, I would have made the offer before I
left office.
I was quite aware of Mr. Faraday's high eminence as a
man of science, and the valuable jiractical service he has
rendered to the ]iublic in that capacity ; but I was to blame in
not having ascertained whether his pecuniary circumstances
made an addition to his income an object to him.
I am sure no man living has a better claim to such a con-
sideration from the State than he has, and I trust the principle
I acted on with regard to the awaixl of civil jiensions will not
only remove away impediments of delicacy and indei>endent
feeling from the acceptance of them, but will add a higher
value to the grant of a pension as an honourable distinction
than any that it could derive from its pecuniary amount.
Ever, my dear Ashley,
Most faithfully yours,
PiOBERT Peel.
Sir James South still endeaYourecl to bring about
the grant thus deferred, and wrote to the Hon. Caroline
Fox, asking her to put the historiette of Faraday in
the hands of Lord Holland, for hiui to lay before
Melbourne. Faraday at first demurred to Sir James
Souths action, but on the advice of his father-in-law,
Barnard, withdrew his demurrer. Later in the year
he was asked to wait on Lord Melbourne at the
Treasury. He has left a diary of the events of the
day, October 26th. According to these notes it
LORD Melbourne's participle. 71
appears that Faraday first had a long talk with
Melbourne's secretary, Mr. Young, about his first
demurring on religious grounds to accept the pension,
about his objection to savings' banks, and the laying-
up of wealth. Later in the day he had a short inter-
view with the First Lord of the Treasury, when Lord
Melbourne, utterl}^ mistaking the nature of the man
before him, inveighed roundly upon the Avhole system
of giving pensions to scientific and literary persons,
which he described as a piece of humbug. He pre-
fixed the word " humbug " with a participle which
Faraday's notes describe as *' theological." Faraday,
with an instant flash of indignation, bowed and with-
drew. The same evening he left his card and the
following note at the Treasury : —
To the Right Hon. Lord Vucount Melbourne^ First Lord of
the Treasury.
October 26.
My Loed, — The conversation Avitli which your Lordship
honoured me this afternoon, including, as it did, your Lord-
ship's opinion of the general character of the pensions given of
late to scientific persons, induces me respectfully to decline
the favour wliich I Ijelieve your Lordship intends for me ; for
I feel that I could not, witli satisfaction to myself, accept at
your Lordship's hands that which, though it has the form of
approbation, is of the character wliich your Lordship so pithily
applied to it-
Faraday's diary says : —
Did not like it much, and, on the whole, regret that friends
should have placed me in the situation in which I found
myself. Lord Melbourne said that "he thought there had
been a great deal of humbug in the whole affair. He did not
ri MICHAEL FARADAY.
mean my affair, of course, but that of the pensions altogether."
... I begged him to understand that I had kno-u-n nothing
of the matter until far advanced, and, though grateful to those
friends who had urged it forward, wished him to feel at
perfect liberty in the affair as far as I was concerned. . .
In the evening I Avrote and left a letter, I left it myself at
ten o'clock at night, being anxious that Lord Melbourne
should have it before anything further was done in the
affair.
However, the matter did not end here. Faraday's
friends were indignant. A caustic, and probably
exaggerated, account — for wliicli Farada}^ disclaimed
all responsibility — of the interview appeared in Frasers
Macjazine, and was copied into TJte Times of Novem-
ber 28th, with the result that, had it not been for
the personal intervention of the King, the pension
might have been refused. The storm, however,
passed away, and the pension of £300 per annum was
^•ranted on December 24th. Years afterwards, writins^
to j\Ir. B. Bell, Faraday said, " Lord Melbourne behaved
very handsomely in the matter."
In Fraser's Magazine for February, 1886 (vol.
xiii., p. 224), is a portrait of Faraday by Maclise,
accompanied by a very amusing biographical notice
by Dr. Maginn. The picture represents Faraday
lecturing, and surrounded by his apparatus. The
article begins thus : —
Here you have him in his glory — not that his position was
inff/orious when he stood before Melbourne, then decorated
with a blue velvet travelling cap, and lounging with one leg
over the chair of Canning ! — and distinctly gave that illus-
trious despiser of "humbug" to understand that he had
mistaken his lad. No ! but here you have him as he first
MtCHAELS PENSION. 73
tiayhed upon the intelligence of mankind the condensation of
the gases, or the identity of the five electricities.
After a lively summary of his career, and the
jocular suggestion that, as the successor of Sir
Humphry Davy, Far-a-day must be near-a-knight
the article continues : —
The future Baronet is a very good little fellow . . . playing
a fair fork over a leg of nuitton, and devoid of any reluctance to
partake an old friend's third bottle. Wc know of few things
more agreeal)]c than a cigar and a bowl of punch (which he
mixes admiral tly) in the society of the unpretending ex-
bookbinder. . . .
Well, although Young got Eroderip to write a sort of
defence of his master, and "Justice B " — mirahile dictu! —
got Hook to print it in the JoJin BuH^ the current of public
feeling could not be stopped : Regina spoke out — William
E,EX, as in duty bound, followed — Melbourne apologised^and
"Michael's pension, Michael's pension" is all right.
In one of his note-books of this period is found
the following entry : —
15 January, 1834.
^yithin the last Aveek have observed twice that a slight
obscurity of the sight of my left eye has happened. It
occurred on reading the letters of a book held about fourteen
inches from the eye, being obscured as by a fog over a space
about half an inch in diameter. This space wns a little to the
right and below the axes of the eye. Looking for the effect
now and other times, I cannot perceive it. I note this down
that I may hereafter trace the progress of the effect if it
increases or becomes more common.
Happily, the trouble did not recur ; but the entry
is characteristic of the habits of accuracy of the man.
Loss of memorj^, unfortunately, early set in. There is
74 MICHAEL FARADAY.
actually a hint of this in the tirst of his letters to
Abbott (p. 7), and references to the trouble and
to dizziness in the head recur perpetually in his
correspondence. Whenever these brain - troubles
threatened, he was compelled to drop all work and
seek rest and chanc:e of scene. He often ran down to
Brighton, which he thought, however, a poor place.
He constructed for himself a velocipede* on which
to take exercise. Tavo or three times he went to
Switzerland for a longer holiday, usually accompanied
by his wife and her brother, George Barnard.
"Physically," says Tyndall, "Faraday was below
the middle size, well set, active, and with extra-
ordinar}^ animation of countenance. His head from
forehead to back was so long that he had usuall}' to
bespeak his hats." In 3^outh his hair was brown*
curling naturally : later in life it approached to white,
and he always parted it down the middle. His voice
Avas pleasant, his laugh was heart}^ his manners when
with young people, or when excited by success in the
laboratory, were gay to boyishness. Indeed, until the
end of the active period of his life he never lost the
capacit}^ for boyish delight, or for unbending in fun
after the stress of severe labour.
'•" " It was probably in a four-\vheelef.l vclociiK.'de that l^avaday was
accustomed, some thirty years ago, to woik his way up and down the
steep roads near Hampstead and Highgate. This machine appears
to have been of his own construction, and was worked by levers and
a crank axle in the same manner as the rest of the foiir--wheeled class."
— The Velocipede : its past, its present , and its future. By J. F. B. Firth.
London, 18G9.
CHAPTER III.
SCIENTIFIC RESEARCHES : FIRST PERIOD.
From first to last the original scientiiic researches ot
Faraday extend over a period of forty-four years,
beginning with an analysis of caustic lime, published
in the Quarterly Journal of Science in 181G, and
ending with his last unfinished researches of 1860
to 1862, on the possible existence of new relations
betAveen magnetism and gravity and between mag-
netism and light. The mere list of their titles tills
several pages in the catalogue of scientific papers
published by the Royal Society.
For convenience of description, these forty-four
years nmy be divided into three periods : the first
lasting from 1816 to 1830, a period of miscellaneous
and in some respects preliminary activity; the second
from 1831 to the end of 1839, the period of the
classical experimental researches in electricity down
to the time when they were temporarily suspended by
the serious state of his health ; the third from 1844,
when he Avas able to resume work, down to 1860, a
period which includes the completion of the experi-
mental researches on electricity, the discovery of the
76 MICHAEL FARADAY.
relations between light and magnetism, and that or
diamagnetism.
Faraday's tirst research was an analysis for Sir
Humphry Daw of a specimen of caustic lime which
had been sent to him by the Duchess of Montrose
from Tuscany. The Qnarterhj Journal of Science, in
which it appeared, was a precursor of the Proceedings
of the Boyal In.^fitution, and was indeed edited bj'
Professor W. F. Brande. Faraday frequent!}' wrote
for it during these years, and took editorial charge ot
it on more than one occasion during Brande's holidays.
The paper on caustic lime was reprinted by Faraday
in the yolume of his " Experimental Researches on
Chemistry and Ph3-sics," prefaced by the following
note : —
I reprint this paper at full length ; it was the beginning of
my communications to the public, and in its results very
important to me. Sir Humphry Davy gave me the analysis
to make as a first attempt in chemistry, at a time when my
fear was greater than my confidence, and both far greater than
my knowledge : at a time also when I had no thought of ever
writing an original paper on science. The addition of his own
comments, and the publication of the paper, encouraged me to
go on making, from time to time, other slight communications,
some of which ajtpear in this volume. Their transference from
the Qnarferh/ into other journals increased my boldness, and
now that fort}^ years have elapsed, and I can look back on
what successive communications have led to, I still hope, much
as their character has changed, that I have not either now or
forty years ago been too bold.
For the next two or three years Faraday was
very closely occupied in the duties of assisting Sir
Humphry Davy in his researches, and in helping to
KESEARCHES BEOTNXINa 77
prepare the lectures for both Davy and Brande. Yet
he found time still to work on his own account. In
1817 he had six papers and notes in the Qiiarteiiy
Journal of Science, including one on the escape of
gases through capillary tubes, and others on wire-
gauze safety lamps and Davy's experiments on fiame.
In 1818 he had eleven papers in the Journal; the
most important being on the production of sound in
tubes by flames, while another was on the combustion
of the diamond. In 1819 he had nineteen papers in
the Qiutrterly Journal, chiefly of a chemical nature.
These related to boracic acid, the composition of
steels, the separation of manganese from iron, and on
the supposed new metal, " Sirium " or " Yestium,"
which he showed to be only a mixture of iron and
sulphur with nickel, cobalt, and other metals.
The year WW was marked in the annals of science
by the discovery, by Oersted of Copenhagen, of the
prime fact of electromagnetism, the deflexion which is
produced upon a magnetic needle by an electric current
that passes either under or over the needle. Often had
it been suspected that there must be some connection
between the phenomena of electricity and those of
magnetism. The similarities between the attractions
and repulsions caused by electrified bodies, and those
due to the magnet when acting on iron, had constantly
suggested the possibility that there was some real
connection. But, as had been pointed out centuries
before by vSt Augustine, while the rubbed amber will
attract any substance if only small or light enough,
being indifferent to its material, the magnet will only
attract iron or compounds of iron, and is totally
78 MICHAEL FARADAY.
iaoperative* on all other substances. Again, Avliile it
had been noticed that in houses which had been,
struck by hghtning knives, needles, and other steel
objects near the path of the electric flash had become
magnetised, no one had been able, b}' using the most
powerful electric machines, to repeat with certainty
the magnetisation of needles. In vain they had tried
to magnetise knives and wires by sending sparks
through them. Sometimes they showed a trace of
magnetism, sometimes none. And in the cases where
some slight magnetisation resulted, the polarity could
not be depended upon. Van Swinden had written
a whole treatise in two volumes on the analogies
between electricity and magnetism, but left tlie real
relation between the two more obscure than ever.
After the invention, in ISOO, of the voltaic pile, which
for the tirst time provided a means of generating a
steady flow or current of electricity, several experi-
menters, including Oersted himself, had again essayed
to discover the long-suspected connection, but with-
out success. Oersted was notoriously a poor experi-
menter, though a man of great philosophical genius.
Having in 1820 a more powerful voltaic battery in
operation than previousl3^ he repeated! the operation
of bringing near to the compass needle the copper wire
that conveyed the current; and, laying it parallel to
the needle's direction, and over or under it, found that
the needle tended to turn into a direction at right
" Except on nickel and cobalt, which are also para-magnetic metals.
+ For a graphic acoouat hy Hansteen of the circnmstances of
Oersted's discovery, see Bence Jones's " Life and Letters of Fumday,"
vol. ii. p- 390.
oersted's discoveuy. 79
angles to the line of the current, the sense of the
deviation depending upon the direction of liow of the
current, and also on the position of the wire as to
whether it were above or below the needle. A current
flowing' from south to north over the needle caused
the north-pointing end of the needle to be deflected
westwards. If tlie wire were vertical, so that the
current flowed downwards, and a compass needle was
brous^ht near the wire on the south side, therefore
tending under the earth's directive influence to point
northwards toward the wire, it was observed that the
effect of the current flowing in the wire was to cause
the north-pointing end of the needle to turn west-
wards. Or, reversing the flow of current, the effect
on the needle was reversed ; it now tended eastwards.
All these things Oersted summed up in the phrase
that " the electric conflict acts in a revolving manner "
around the Avire."^ In modern phraseology the whole
of the actions are explained if one can conceive that
the effect of the electric How in the wire is to tend to
make the north pole of a magnet revolve in one sense
around the wire, whilst it also tends to make the
south pole of the magnet revolve around the wire in
the other sense. The nett result in most cases is that
* " To the effect which takes place in this conductor [or uniting
wire] and in the surrounding space, we shall give the name of the
coiijiict of electricity.'" ....
"From the preceding facts wo ma}'' likewise collect that this con-
flict performs circles ; for without this condition, it seems impossible
that the one part of the uniting wire, when placed helow the magnetic
pole, should drive it towards the east, and when placed above it
towards the west ; for it is the nature uf a circle that the motions in
opposite parts should have an opposite direction." — H. C. Oeksted,
Ann. of I'hxL, Oct., 1820, pp. 273—276.
-SO MICHAEL FARADAY.
the magnetic needle tends to set itself square across
the line of the current. Oersted himself was not too
clear in his explanations, and seems, in his later
papers, to have L^st sic^ht of the circular motion
amidst repulsions and attractions.
This discovery, which showed Avhat was the
freometrieal relation between the macmet and the
current, also showed why the earlier attempts had
failed. It was requisite that the electricity should
be in a state of steady tioAv ; neither at rest as in the
experiments with electric charges, nor yet in capricious
or oscillatory rush as in those with spark-discharges.
Farada}', adverting a quarter of a century later to
Oersted's discovery, said : " It burst open the gates of
a domain in science, dark till then, and tilled it with
a flood of light."
The very day that Oersted's memoir was pub-
lished in England, Davy brought a copy down into
the laboratory of the Royal Institution, and he and
Faraday at once set to work to repeat the experi-
ments and verify the facts.
It is a matter of history how, on the publication
of Oersted's discovery, Ampere leaped forward to
creneralise on electromagnetic actions, and discovered
the mutual actions that may exist between two
currents, or rather between tw^o conducting wires that
carrj' currents. They are found to experience mutual
mechanical forces urging them into parallel prox-
imity. Biot and Laplace added to these investiga-
tions, as also did Arago. Davy discovered that the
naked copper wire, while carrying a current, could
attract iron filings to itself — not end-ways in adherent
o
A PARADOXICAL PHENOMENON. 81
tufts, as the pole of a magnet does, but laterally, each
filing or chainlet of tilings tending to set itself
tangentially at right angles to the axis of the
wire.
This curious right-angled relation between electric
flow and magnetic force came as a complete paradox
or puzzle to the scientific world. It had taken
centuries to throAv off' the strange unmechanical ideas
of force which had dominated the older astronomy.
The epicyclic motions of the planets postulated by
the Ptolemaic system were in no way to be accounted
for upon mechanical principles. Kepler's laAvs of
planetary motion were merely empirical, embodying
the results of observation, until Newti^n's discovery of
the laws of circular motion and of the principle of
universal gravitation placed the planetary theory on
a rational basis. NcAvton's laws required that forces
should act in straight lines, and that to every action
there should be an equal and opposite reaction. If
A attracted b, then b attracted A with an equal force,
and the mutual force must be in tlie line drawn from
A to B. The discovery by Oersted that the magnet
pole was urged by the electric wire in a direction
transverse to the line joining them, appeared at first
sight to contravene the ideas of force so thoroughly
established by Newton. How could this transver-
sality be explained ? Some sought to explain the
effect by considering the conducting wire to operate
as if made up of a number of short magnets set
transversely across the wire, all their north poles
being set towards the right, and all their south poles
towards the left. Ampere took the alternative view
G
S'2 MICHAEL FARADAY.
that the iiiagiiot might bo rcgardod as oijuivaloiit to a
number of electric currents circuhitiug transversely
around the core as an axis. In neither case was the
exphxnation complete.
Fai-aday's scientitic activities in the year ]S2()
Avere very marked. New researches on steel had
been going on for soine months. It had been
hoped that by alloying iron with some other metals,
such as silver, platinum, or nickel, a non-rusting
alloy might be found. This idea took its rise from
the erroneous notion that meteoric iron, which is
ri(;hly alloyed with nickel, does not rust. Faraday
found nickel steel to be more readily oxidised, not
less, than ordinary steel. The platinum steel was
also a failure. Silver steoi was of more interest,
though it Avas found imjiossible to incorporate in
the alloy more than a small percentage of silver.
Nevertheless, sih^er steel was used for some time
Ly a Sheffield firm for manufacture of fenders.
The alloys of iron with platinum, iridium, and
rhodium were also of no <rrcat use. But the re-
search demonstrated the surprising effects which
minute quantities of other metals may have upon
the quality of steel. Occasionally in later life Faraday
would present one of his friends with a razor made
from his own special steel. A paper on the use of
alloys of steel in surgical instrument making was
published in the Qmirteiiy Journal in collaboration
with Mr. Stodart. Faraday also read his first paper
before the Royal Society on two new compounds of
chlorine and carbon, and on a new con)pound of
iodine, carbon, and hydrogen. He also succeeded in
TWO YEARS WASTED. 83
makin;:^ artiticial plumbago from charcoal. In writing
to his friend Professor G. de la Rive, he gives a l(:>ng
and chatty abstract of his researches on the alloys of
steel. They appear to have originated in son:ie anah-ses
ot' wootz or Indian steel, a material which, when etched
Avith acid, shows a beautifully damascened or reti-
culated surface. This effect Faraday never found
with pure steel, biu imitated it successfuUv with a
steel aUoyed with " the n:ietal of alunhne," an element
which do"\\'n to that time had not been isolated. He
then describes the rhodium, silver, and nickel steels,
and mentions incidentally how he has been surprised
to discover that he can volatilise silver, and that he
cannot reduce the metal titanium. He is doubtfid
whether this metal '' ever has been reduced at all in
the pure state." [It can now be readily reduced
either in the electric arc m' by the use of metallic
aluminimn.] He winds up the letter with the Avords :
'• Pray pity us that, after two years' experin:ients, we
have got no further : but I am sure, if you knew the
labour of the experiments, you would applaud us for
our perseverance at least."
In 1821, the xear of his marriage, came the tirst of
the important scientitic discoveries which brought
him international fame. This was the discovert' of
the electromagnetic rotations. It appears that
Oersted's brilliant flash of insight that the ■ electric
conflict acts in a revolving manner " upon the pole of
the neighbouring compass needle had been lost sight
of in the discussions which followed, and to Avhich
allusion has been made above. All the world was
thmking about attractions and repulsions. Two men,
84 MICHAEL FARADAY.
however, seem to have gone a little further in their
ideas. Dr. WoUaston had stiggested that there onght
to be a tendency, when a magnet pole was presented
towards a straight conducting wire carrying a current,
for that contlucting wire to reyolve around its own
axis. This etiect — though in recent years it has been
observed by Mr. George Gore — he unsuccessfully tried
to observe bv experiments. He came in April, Ks21.
to the laboratory of the Royal Institution to make an
experiment, but Avitbout result. Faraday, at the
request of his friend Phillips, who was editor of the
Anutd^ of FIdlosopJnj, wrote for that magazine in
Jidy. August, and September a historical sketch oi
electromagnetism down to date. This was one of
the very few of Faraday's writings that was anonymous.
It was simpl}' signed " ^[." This is in vol. iii. p. 107.
On p. 117 the editor says: "To the historical sketch
o( electromagnetism with which I have been favoured
bv my anonymous correspondent. I shall add a sketch
of the discoveries that have been made by ^Ir.
Faraday of the Eoyal Institution." In the cotn-se of
this Avork Faraday repeatetl for his own satisfaction
almost all the experiments that he described. This
led him to discover that a wire, included in the circuit,
but mounted so as to hang Avith its lower end in a
pool of quicksilver, coidd rotate around the pole of a
magnet : and conversely that if the wire were tixed
and the pole of the magnet free to move, the latter
would rotate around the former. " I did not realise."
he wrote, " Dr. AVollaston's expectation of the rotation
of the electromagnetic wire around its axis." As was
so often his custom, he had no sooner finished the
LETTER TO DE LA lUVE. S5
research for publication than he dashed off a brief
smnmary of it in a letter to one of his friends. On
this occasion it was Professor G. de la Rive, of Geneva,
who was the recipient of his confidences, On
September 12 he wrote : —
I am much flattered and encouraged to go on by your good
opinion of what httle things I have been able to do in science,
and especially as regards the chlorides of carbon.
You partly reproach us here with not sufficiently esteeming
Amperes experiments on electromagnetism. Allow me to
extenuate your oiiinion a little on this point. ^Yith regard to
the experiments, I hope and trust that due weight is allowed
to them ; but these you know are few, and theory makes up
the great part of what M. Ani}>ere has published, and theory
in a great many points unsupported by experiments when they
ought to have been adduced. At the same time, ^L Ampere's
ex]")eriments are excellent, and his theory ingenious ; and, for
myself, I had thought very little about it Ijefore your letter
came, simply because, heing naturally sceptical on philosophical
theories, I thought there was a great want of experimental
evidence. Since then, however, I have engaged on the subject,
and have a paper in our "Institution Journal," which will
iippear in a week or two, and that will, as it contains experi-
ment, be immediately applied by M. Ampere in support of his
theory, much more decidedly than it is Ly myself. I intend
to enclose a copy of it to you with the other, and only want
the means of sending it.
I find all the usual attractions and repulsions of the
magnetic needle by the conjunctive wire are decep)tions, the
motions being not attractions or repulsions, nor the result of
any atti'active or repulsive forces, but the result of a force in
the wire, which instead of bringing the jtole of the needle
nearer to, or further from the wire, endeavours to make it
move round it in a never ending circle and motion whilst the
86 MICHAEL FAKADAV.
battery remains in action. I have succeeded not only in
showing the existence of this motion theoretically, but experi-
mentally, aud have been able to make the wire revolve round
a magnetic pole, or a magnetic pole round the wire, at pleasure.
The law of revolution, and to which all the other motions
of the needle and wire are reducible, is simple and
beautiful.
Conceive a portion of connecting wire north and south, the
north end being attached to the positive pole of a battery, the
south to the negative. A north magnetic pole would then pass
round it continually in the apparent direction of the sun, from
east to west above, from went to east V^elow.
Reverse the connections with the battery, and the motion
of the pole is rc-verse'] ; or if the south pole be made to revolve,
the motions will be in the opposite directions, as with the
north pole.
If the wire be made to revolve round the pole, the motions
are according to those mentioned. In the apparatus I used
there were but two plates, and the directions of the motions
were of course* the revenje of those with a battery of several
pairs of plates, and which are given above. Xow I Ixave been
able, experimentally, to trace this motion into its various forms
as exhibited Vjy Ampere's, Xelice's, <fec,, and in all cases to show
that the attractions and repulsions are only appearances due
to this circulation of the pole, to show that dissimilar poles
repel as well as attract, and that similar poles attract as well as
repel, and to make, I think, the analogy between the helix and
common bar magnet far stronger than before. But yet T am
by no means decided that there are currents of electricity in
the common magnet.
I have no doubt that electricity puts the circles of the helix
into the same state as those circles are in, that may be con-
ceived in the bar niagnet, but I am not certain that this state
is directly dependant on the electricity, or that it cannot be
X>roduced by other agencies ; and therefore, until the presence
of electrical currents be proved in the magnet by other than
* This hi an hrrOT (hxc to hasta in writintr.
LEAVES FROM THE XOTE-BOOK. 87
ma^^netical effects, I shall remain in doubt about Ampere's
tlieor)^
L Wishing you all health and happiness, and waiting for news
from you,
I am, my dear Sir, your very obliged and grateful
M. Faraday,
The reference at the be^^inninc^ ot this letter to
the chlorides of carbon has to do with his discovery
communicated to the Royal Society. Later in the
year, a joint paper on another compound of carbon
and chlorine, by himself and his friend Eichard
Phillips, was sent in. Both were ])rinted together in
i\\Q Fhilosopliical Ti-an.^artions of 1821.
The folloAving is an extract from Faraday's labora-
tory book relating to the discovery. The accoimt is
incomplete, a leaf having been torn out :—
1.^21, Sept. 3.
The effort of the wire is always to pnss off at a riglit angle
from the pole, indeed to go in a circle round it, so when either
pole was brought up to the wire perpendicular to it and tu tlie
radius of the circle it described, there was neither attraction
nor repulsion, but the moment the pole varied in the slightest
manner either in or out, the wire moved one way or the other.
The poles of the magnet act on the bent wire in all positions
and not in the direction on/// of any axis of the magnet, so
that the current can hardly be cylindrical or arranged round
the axis of a cylinder?
From the motion above a north magnet pole in the centre
of one of the circles should make the wire continually tarn
round. Arranged amagnet needle in a glass tube with mercury
about it, and l.iy a cork, water, itc, supported a connecting
Avire so that the upjier end should go into the silver cui) and
its mercur}^ and the lower move in a channel of mercury round
88
MICHAEL FARADAV.
the pole of the needle. The battery arranged with the -wire as
before. In this -way got the revolution of the "wire round the
pole of the magnet. The dkection was as follow, looking from
above down : —
(Facmmile of Original Sketch.)
Very satisfactory, but make more sensible apparatus-
Tuesday. Se])t. 4.
Apparatus for revolution of wire and magnet. A deep
basin with bit of Avax at bottom and then tilled with mercury.
A magnet stuck upright in was so that pole just above the
surface of mercury. Then piece of wire floated by cork at
lower end dipping into mere- and above into silver cup as
before :—
•■'W
Fig. 3. (Fac^^imile uf Ukigixal Sketch.)
The research on the electroinao-netic rotations,
which was published in the Qnt/rterb/ Journal of
Science for October, 1821 (and reprinted in the second
Tohtme of the '^ Experimental Researches in Elec-
tricity '% was the occasion of a very serious misunder-
standing with Dr. Wollaston and his friends, which
at one time threatened to cause Earaday's exchision
SCENES IN THE LABORATORY. 89
from the RoA-al Society. Faraday's prompt and frank
action in appealing to iJr. AVollaston saved him in a
very unpleasant crisis : and the latter came three or
four times to the laboratory to witness the experi-
ments. On Christmas Day of the same year, Faraday
succeeded in making a wire through which an electric
current is passing move under the influence of the
earth's magnetism alone. His brother-in-law, George
Barnard, who was in the laboratory at the time,
wrote: — "All at once he exclaimed, 'Do you see, do
you see, do you see, George ? ' as the wire began to
revolve. One end I recollect was in the cup of quick-
silver, the other attached above to the centre. I shall
never forget the entliusiasm expressed in his face
and the sj^arkling in his eyes ! "
In 1S22 little was added to Faraday's scientific
work. He had a joint paper Avith Stodart on steel
before the Royal Society, and in the Quarterly
Journal two short chemical papers and four on
electromagnetical motions and magnetism. He had
long kept a commonplace book in which he entered
notes and queries as well as extracts from books and
journals ; but this year he began a fresh manuscript
volume, into which he transferred many of the
queries and suggestions of his own originating. This
volume he called "Chemical Notes, Hints, Suggestions,
and Objects of Pursuit." It contains many of the
germs of his own future discoveries, as the following
examples show : —
Convert magneti.sm into electricity.
Do pith baits diverge Ijy disturbance of electricities in
consequence of induction or not?
90 MICHAEL FAKADAY.
General effects ot compression, either in condensing gases,
01" producing solutions, or even giving combinations at low
tem[)eratures.
Light through gold leaf on to zinc or most uxidable metals,
these being poles — or on magnetic bars.
Transparency of metals. Suii's light through gold leaf.
Two gold leaves made poles— light passed through one to the
other.
Whenever any query found an answer, he drew
his pen through it and added the date. In front of
the book — probably at some later time — he wrote
these Avords : —
I already owe much to these notes, and think such a
collection "\vorth the making by every scientific man. 1 am
sure none "would think the trouble lust after a year's experience.
A striking:;' example had already occurred of similar
suggestive notes in the optical queries of Sir Isaac
Xewton.
In another manuscript notebook occur the follow-
ing entries under date of September 10, 1821 : —
•2 similar poles though they repell at most distances attract
at very small distances and adhere. Query wh)-
Could not magnetise a plate of steel so as to resemble tlat
spiral. Either the magnetism would be very ^\eak and
irregular or there would be none at all.
These are interesting as showing how Faraday
was educating himself by continual experiment. The
explanation of each of these paradoxes has long
passed into the commonplace of physics ; but they
would still puzzle many wdio have learned their
science bookishl^' at second-hand.
AN UNSUCCESSFUL EXPERIMENT. 91
It will be noted that amongst the entries cited
above there are two of absolutely capital importance,
one foreshadowing the great discovery of magneto-
electric induction, the other indicating how the
existence of electro-optical relations was shaping
itself as a possibility in Faraday's mind. An entry in
his laboratory book of September 10 is of great
interest : —
Polarised a ray of lamp light by reflection, and endeavoured
to ascertain whether any depolarising^ action [is] exerted on it
by water placed between the poles of a voltaic battery in a
glass cistern ; one WoUaston's trough used ; the fluids
decomposed were pure water, weak solution of .sulphate of
soda, and strong sulphuric acid : none of them had any effect
on the polarised light, either when out of or in the voltaic
circuit, so that no i)articular arrangement of particles could be
ascertained in this way.
It may be added that no such optical effect of
electrolytic conduction as that here looked for has
yet been discovered. The experiment, unsuccessful
at that da}^ remains still an unsuccessful one. A
singular interest attaches to it, however, and it was
repeated several times by Faraday in subsequent
years, in hope of some results.
In 1S28 Faraday read two papers to the Royal
Society, one on Liquid Chlorine, the other on the
Condensation of several Gases into Liquids. No
sooner was the work completed than he dashed off a
letter to \)e la Rive to tell him what he had accom-
plished. Under date March 24, 1828, he writes : —
I have been at work lately, and ohtained results which I
hope you will approve of. I have been interrupted twice in
02 MICHAEL FARADAY.
the course of experiments Viy explosions, both in the course of
ei^ht days— one burnt my eyes, the other cut them ; but
fortunately escaped with slight injury only in both cases, and
am now nearly well. Daring the winter I took the oppi>rtunity
of examining the liyJrate of chlorine, and analysing it : the
results, which are not very important, will appear in the next
number of the Qiuirttrh/ Journal, over which I have no
intiuence. Sir H. Davy, on seeing my paper, suggested to me
to work with it under pressure, and see what would ha]>pen by
heat, ttc. Accordingly I enclosed it in a glass tube hermetically
sealed, heated it, obtained a change in the substance, and a
separation into two different fluids ; and upon farther examina-
tion I found that the chlorine and water had separated from
each other, and the chlorine gas, not being able to escape, had
condensed into the liijuid form. To prove that it contained
no water, I dried some chlorine gas, introduced it into a long
tube, condensed it, and then cooled the tube, and again
obtained fluid chlorine. Hence what is called chlorine gas is
the vapour of a fluid
I expect to be able to reduce many other gases to the liquid
form, and promise myself the pleasure of writing you abnut
them. I hope you "^ill honour me with a letter soon.
I am, dear Sir, very faithfully, your obedient servant,
M. Faraday.
The work of liquefying the gases had been taken
up by Farada}' during his hours of liberty from other
duties. It was probably his characteristic dislike to
'^ doubtful knowdedge " -which prompted him to re-
examine a substance "which had at one time been
regarded as chlorine in a solid state, but Avhich DaYy
hr ISIO had demonstrated to be a hydrate of that
element. The tirst Avork was, as narrated aboYe, to
make a new analysis of the supposed substance. This
analYsis, duh' written out, was submitted to Sir
CHLORINE LIQUEFIED. 93
Humphry, who, without statmg precisely what results
he anticipated might follow, suggested heating the
hyd.rate under pressure in a hermetically sealed glass
tube. This Faraday did. When so heated, the tube
filled with a yellow atmosphere, and on cooling was
found to contain two liquids, one limpid and colour-
less like water, the other of an oily appearance.
Concerning this research a curious story is told in the
life of Davy. Dr. Paris, Davy's friend and biographer,
happened to visit the laboratory while Faraday was
at work on these tubes. Seeing the oily liquid, he
ventured to rally the young assistant upon his care-
lessness in employing greasy tubes. Later in the day,
Faraday, on filing oft' the end of the tube, was startled
by finding the contents suddenly to explode ; the
oily matter completely disappearing. He speedily
ascertained the cause. The gas, liberated from com-
bination with Avater by heat, had under the pressure
of its own evolution liquehed itself, only to re-expand
with violence when the tube was opened. Early the
next day Dr. Paris received the following laconic
note : —
Dear Sie,—
The oil you noticed yesterday turns out to be liquid
ciik)rine.
Yours faithfully,
M. Faraday.
Later he adopted a compressing syringe to condense
the gas, and again succeeded in liquefying it. DaA^y,
who added a characteristic note to Faraday's published
paper, immediately applied the same method of
liquefaction by its own pressure to hydrochloric acid
94 MICHAEL FARADAY.
o;;is ; and Faraday reduced a number of other gases
b}^ the same means. These researches were not "with-
out danger. In the prehmmary experiments an ex-
plosion of one of the tubes drove thirteen fragments
of glass into Faraday's eye. At the end of the year he
drew up a historical statement on the liquefaction of
gases, which was published in the Quarterb/ Journal
for January, 1824. A further statement by him was
published in the FJ/ ilosopJiicul Magaziiif for 1S3G :
and in Fs4-I- his further researches on the lique-
faction of gases were published in the P]tih)sop]tical
Tr(rnsaction><.
In 1824- Faraday ao-ain brought to the Eoyal
Society a chemical discovery of first importance.
The paper was on some new compounds of carbon
and hydrogen, and on certain other products obtained
during decomposition of oil by heat. From condensed
oil-gas, so obtained, Faraday succeeded in separating
the liquid kno'\\Ti as benzin or benzol, or, as he named
it at the time, bicarburet of hydros'en. It has since
its discover}' formed the basis of several great chemical
industries, and is manufactured in vast quantities.
Prior to the reading of this paper he had, as we have
already related, been elected a Fellow of the Royal
Society, an honour to which he had for some 3'ears
aspired, and which stood alone in his regard above
the scientific honours of later years.
In this year he tried, amongst his unsuccessful
experiments, two of singular interest. One was an
attempt to find Avhether two crystals (such as nitre)
exercised upon one another any polar attractions like
those ot two lodestones. He suspended them by
ItESEARCH ON OPTICAL GLASS. 95
fibres of cocoon silk, and, finding this niaterial not
delicate enough, by spider-lines. The other was an
attempt to discoAxr magneto-electricity. For various
reasons he concluded that the approximation of the
pole of a powerful magnet to a conductor carrying a
current would have the effect of diminishing the
amount of that current. He placed magnets within
a copper wire helix, and observed Avith a galvanometer
whether the current sent through the circuit of the
helix by a given battery was less when the magnet
was absent. The result was negative.
In this year also began the laborious researches
on optical glass, which though in themselves leading to
no immediate success of counnercial value, nevertheless
furnished Faraday Avith the material essential at the
time for the making of the most momentous of all
his discoveries. A committee had been appointed by
the President and Coimcil of the Royal Society for
the improvement of glass for optical purposes,
and Faraday was amongst those chosen to act
upon it.
In 1825 the Royal Society Committee delegated
the investigation of optical glass to a sub-committee
of three, Herschel (afterAvards Sir John), Dollond
(the optician), and Faraday. The chemical part, in-
cluding the experiniental n:ianufacture, Avas entrusted
to Faraday. Dollond Avas to Avork the glass and test
its cpialities from the instrument maker's point of
view, Avhilst Herschel Avas to examine its refraction,
dispersion, and other physical properties. This sub-
committee Avorked for nearly live years, though by
the removal of Herschel from England its number Avas
96 ^[ICHAEL FARAPAV.
reduced to uxo. In 1827 the work became more
arduous. Faraday thus writes : —
The President and Council of the Royal Society applied to
the President and Managers of the Pioyal Institution for leave
to erect on their juemises an experimental room "with a
furnace, for the purpose of continuing the investigation on the
manufacture of optical gla-s. They were guided in this hy the
desire which the Royal Institution has always evinced to
assist in the advancement of science ; and the readiness with
which the application was granted shewed that no mistaken
notion had been formed in this respect. Asa member of both
bodies. I felt much anxiety that the investigation should he
successful. A room and furnaces were built at the Royal
Institution in September, 18i?7, and an assistant was engaged,
Sergeant Anderson, of the Royal Artillery. He came on the
3rd of December.
Anderson, who was thus made assistant to P'araday,
remained in that capacity till his death in 1866. He
was a juost devoted servant. In a footnote to the
■■ Experimental Researches " {\o\. iii. p. 3) Faraday in
1845 wrote of him : —
I cannot resist the occasion that is thus- offered me of
mentioning the name of ^Ir. Anderson, who came to nie as an
assistant in the glass experiments, and has remained ever since
in the laboratory uf the Royal Institution. He assisted uie in
all the researches into which I have entered since that time ;
and to his care, steadiness, exactitude, and faithfulness in tlie
performance of all that has been committed to his charge. I
am much indebted. — M. F
Tyndall, who hnd a great admiration for Anderson,
declared that his njerits as an assistant might be
summed up in one phrase — blind obedience. The
stor}' is told of him by Benjamin Abbott : —
andekson's obedience. 97
Sergeant Anderson . . . was chosen simply because of
the habits of strict obedience his military training had given
him. His duty was to keep the furnaces always at the same
heat, and the water in the ashpit always at the same level. In
the evening he Avas released, but one night Faraday forgot to
tell Anderson he could go home, and early next morning he
found his faithful servant still stoking the glowing furnace, as
he had been doing all night long.
The research on optical glass "was viewed askance
by several parties. The expenditure of money which
it involved was one of the " charges " hurled against
the Council of the Royal Society by Sir James South
in 1830. Nevertheless it Avas deemed sufficiently
important to receive powerful support, as the follow-
ing letter shows : —
Admiralty, 20 Dec, 1827.
SiE,
I hereby request, on behalf of the Board of Longitude,
that you will continue, in the furnace built at the Royal
Institution, the experiments on glass, directed by the joint
Committee of the Royal Society and the Board of Longitude'
and already sanctioned by the Treasury and the Board of
Excise.
I am, Sir, >
Your obedient servant,
Thomas Young, M.D.,
Michael Faraday, Esq., Sec. Bd. Long.
Royal Institution.
In February, 1825, Faraday's duties toAvards the
Royal Institution were someAvhat modified. Hitherto
he had been nominally a mere assistant to Davy
and Brande, though he had occasionally undertaken
lectures for the latter. Now, on Davy's recommenda-
tion, he was, as we have seen, appointed by the
H
98 MICHAEL FARADAY.
managers Director of the Laboratory under the super-
intendence of the Professor of Chemistry. He was
reUeved, " because of his occupation in research," Irom
his duty as chemical assistant at the lectures.
The research on optical glass "was not concluded
till 1S2P. when its results were communicated to the
Royal Society in the Bal^erian lecture of that year — a
memoir so long that it is said three sittings Avere
occupied in its delivery. It is printed ni e.'ienso in
the P]iilo--«jp]ilriil Trii iisocfioiis of 1880. It opens
as f(.)ll[)ws : —
^\']lL'll the liliilo^-ojilier dc^irei^ td apply glass in the coii-
-stiuction of iierfcct instruments, and especially' the achroniatiL-
telescope, its manufacture is found lialile to imperfections su
important and so ditiicult to avoid, that science is frequently
stopped in her prog^vess by them — a fact fully proved by the
circumstance that Mr. l)ol]ond, one of our first opticians, has
not been able to obtain a disc of tiint ylass 4^ inches in diameter,
tit for a telescope, within the last five years ; or a similar disc,
of 5 inches, within the last ten years.
This led to the appointment by Sir H. Davy of the Eoyal
Society Committee, and the Government removed the excise
restrictions, and xuidertook to bear all the ex])enses as long as
the investig-atiou otfered a reasonable hope of success.
The experiments were begun at the Falcon Glass Works,
three miles from the Eoyal Institution, and continued there in
1825, 1826, and to Sept., Ls27, when a room was built at the
Institution. At tirst the inijuiry was pursued principally as
related to tiint and crown glass ; but in September, 1828, it
was directed exclusively to the preparation and perfection of
peculiar heavy and fusible glasses, from which time continued
progress has been made.
In 1830 the experiments on glass-making were
stopped..
In 1S31 the Committee for the Improvement of
GLASH-MAKINfi LAID ASIDE. 99
Glass for Optical Purposes reported to the Royal
Society Council that the telescope made with Mr.
P\araday's glass had been examined by Captain Kater
and Mr. Pond. " It bears as great a power as can
reasonably be expected, and is very achromatic. The
Committee therefore recommend that Mr. Faraday be
requested to make a perfect piece of glass of the
largest size that his present apparatus Avill admit, and
also to teach some person to manufacture the glass
for general sale."
In answer to this Faraday sent the following letter
to Dr. Roget, Sec. R.S. :—
[M. Fan(<Ia?j to P. M. Eoget]
Pvoyal Institution, July 4, 1831.
Dear Sir,— I send you herewith four large and two small
manuscript volumes relating to optical glass, and comprising
the journal book and sub-committee book, since the period
that experimental investigations commenced at the lioyal
Institution.
With reference to the request which the Council of the
Royal Society have done me the honour of making— namely,
that I should continue the investigation — I should, under cir-
cumstances of perfect freedom, assent to it at once ; but obliged
as I have been to devote the whole of my spare time to the ex-
periments already described, and consequently to i-esign the
pursuit of such philosophical inquiries as suggested themselves
to my own mind, I would wish, under the present circumstances,
to lay the glass aside for a while, that I may enjoy the pleasure
of working out my own thoughts on other subjects.
If at a future time the investigation should be renewed, I
must beg it to be clearly understood I cannot promise full
success should I resume it : all that industry and my abilities
can effect shall be done ; but to perfect a manufacture, not
being a manufacturer, is what I am not bold enough to promise
I am, &c.,
M. Fakaday.
100 MICHAEL FARADAY.
The Optical glass "was a failure, so far as concerned
the original hope that it "would lead to great im-
provements in telescopes. Nevertheless it furnished
scientific men with a new material, the " heavy glass "
consisting essentiall}' of boro-silicate of lead, for which
sundr}^ uses in spectroscopy and other optical instru-
ments have since been found.
In 1845 Faraday added this note : —
I consider our results as negative, except as regards any
good that may have resulted from my heavy glass in the hands
of Amici (who applied it to microscoi)es) and in my late
experiments on light.
These were the famous experiments on magneto-
nptics and diauiagnetism. Incidentally the research
had led also to the permanent engagement of Sergeant
Anderson as assistant to Faradaj\
During these years, from 1825 to 1829, which had
been thus occupied in an apparently fruitless quest,
he had been far from idle. He had s^one on con-
o
tributing chemical papers to the Philosopldcal
Tr cm sad ions and to the Qivarterly Journal. These
dealt wit sulpho-naphthalic acid, with the limits of
vaporisation, with caoutchouc, bisulphide of copper,
the fluidity of sulphur and phosphorus, the diffusion
of gases, and the relation of w^ater to hot polished
surfaces. He had also originated at the Royal Insti-
tution the Friday evening discourses (see p. 33), the
first of Avhich he held in 1826. For some years he
himself delivered no inconsiderable portion of these
discourses every session. In 1826 he gave six, in
1827 three, in 1828 five, in 1829 six, and these in
addition to his regular afternoon courses of six or
RESEARCHES AND LECTURES. 101
eight lectures on some connected subject. He had
also, in 1826, begun the Christmas lectures adapted
to a juvenile audience, and had in 1827 given a course
of twelve lectures at tlie London Institution in
Finsbury Circus. In addition to these labours he
had, in 1827, brought out the lirst edition of his book
on " Chemical Manipulation." In 1829 he began his
lectures at the Royal Military Academy at Woolwich,
which continued till 1849.
The year 1830 may be regarded as the close of
the first period of Faraday's researches, during which
time, though much of his labour had been of a
preparatory and even desultory kind, it had been a
training for the higher work to come. He had made
three notable discoveries in chemistry, the new sub-
stances benzol and butylene, and the solubility of
naphthalene in sulphuric acid forming the first of a.
new class of bodies, the sulpho-acids. He had also
made an important discovery in physics, that of the
electromagnetic rotations. He had already published
sixty original papers, besides many notes of lesser
importance, nine of these papers being memoirs in the
F kilo soplt leal Transactions. He had already begun
to receive from learned societies, academies, and
universities the recognition of his scientitic attain-
ments, and he had established firmly both his own
reputation as a lecturer, and the reputation of the
Royal Institution, which was the scene of his lectures.
CHAPTER, IV.
SCIENTIFIC KESEAllCHES: SECOND PERIOD.
With the year 1N31 begins the period of the cele-
brated " Experimental Researches in Electricity and
Magnetism." During the 3^ears which had elapsed
since his discovery of the electromagnetic rotations in
1S23, Faraday, though occupied, as Ave have seen, with
other matters, had not ceased to ponder the relation
between the magnet and the electric current. The
great discoveries of Oersted, Ampere, and Arago had
culminated in England ia two results : in Faraday's
discovery that the wire which carries an electric
current tends to revolve around the pole of a neigh-
bouring magnet: and in Sturgeon's invention of the
soft-iron electromagnet, a core of iron surrounded by
a coil of copper wire, capable of acting as a magnet at
will when the electric current is transmitted to the
coil and so caused to circulate around the iron core.
This production of magnetism from electricity, at
will, and at a distance, by the simple device of send-
ing the electricity to circulate as a current around
the central core of iron was then, as now, a cause of
much speculation. The iron core Avhich is to be
made temporarily into a magnet stands alone, isolated.
FORESH ADCnVI XO.S. 1 0-"^
Though surrou ruled out\\'ai'dly \)y the, niagnrlisinr^
coil of copper wire, it docs not touch it; nay, must be
screened from contact with it by appropriate insula-
tion. The electric current entering the copper coil at
one end is confined from leaving the copper wire by
any lateral path : it must circulate around each and
every convolution, nor be permitted to flow back by
the return-wire until it has performed the required
amount of circulation. That the mere external
circulation of electric current around a totally dis-
connected interior core of iron should maL^netise that
core ; that the magnetisation should be maintained so
long as the circulation of electricity is maintained ;
and that the maQ-netisinii: forces should cease so soon
as the current is stopped, are facts, familiar enough to
every beginner in the science, but mysterious enough
from the abstract point of view. Faraday was firmly
persuaded that, great as had been these discoveries of
the production of magnetism and magnetic motions
from electricity, there remained other relations of no
less importance to be discovered. Again and again
his mind recurred to the subject. If it were possible
to .use electricity to produce magnetism, why should
not the converse be true ? In 1822 his notebook
suggestion was, as we have seen, " Convert magnetism
into electricity." Yes, but how ?
He possessed an intuitive bent of mind to inquire
about the relations of facts to one another. Convinced
by sheer converse with nature in the laboratorj^, of the
correlation of forces and of the conservation of energy
long before either of those doctrines had received dis-
o
tinct emmciation as principles of natural philosophy,
104 MICHAEL FAKADAY.
he seems never to have viewed an action without
thinking of the necessaiy and appropriate reaction ;
never to have deemed any ph3'sical relation complete
in which discovery had not been made of the converse
relations for which instinctivel}' he sought. So in
December, 1824, Ave find him experimenting on the
passage of a bar magnet through a helix of copper wire
(see Quarterly Journal for Jul}", 1S25), but without
result. In November, 1825, he souo^ht for evidence that
might prove an electric current in a wire to exercise
an influence upon a neighbouring wire connected to a
galvanometer. But again, and yet again in December
of the same year, the entry stands " Xo result." A
third failure did not convince him that the search
was hopeless : it showed him that he had not yet
found the right method of experimenting. It is
narrated of him how at this period he used to carry
in his waistcoat pocket a small model of an electro-
mao'netic circuit — a straioht iron core about an inch
long, surrounded by a few spiral turns of copper Avire
— which model he at spare moments Avould take out
and contemplate, using it thus objectively to concen-
trate his thoughts upon the problem to be solved.
A copper coil, an iron core. Given that electricity
Avas floAving through the one, it evoked magnetism in
the other. What Avas the converse ? At first sight
it might seem simple enough. Put magnetism from
some external source mto the iron core, and then try
Avhether on connecting the coj^per coil to a galvano-
meter there Avas any indication of an electric current.
But this AA^as exactly Avhat Avas found not to result.
And not Faraday alone, but others, too, Avere foiled
OTHER men's failures. 105
ill the hope of observing the expected converse. Not
all who tried were as wise or as frank as Faraday in
confessing faihu'e. Fresnel, in the height of the fever
of Oersted's (hscovery, had announced to the Academy
of Sciences at Paris, on the Gth of November, 1820,
that he had decomposed water by means of a magnet
Avhich was laid motionless within a spiral of wire.
Emboldened by this announcement, Ampere remarked
that he too had noticed something in the way of
production of currents from a magnet. But before
the end of the year both these statements were with-
drawn by their authors. Again, in the year 1822,
Ampere, being at Geneva, showed to Professor A. de
la Rive in his laboratory a number of electromagnetic
ex[)eriments from his classical researches ; and amongst
them one* which has been almost forgotten, but
which, had it been followed up, would assuredly have
led Ampere to the discovery of the induction of
currents. In the experiment in question a thin copper
ring, made of a narrow strip folded into a circle, was
hung inside a circular coil of wire, traversed by a
current. To this apparatus a powerful horse-shoe
magnet was presented ; and De la Rive states that,
when the magnet was brought up, the suspended ring
was observed sometimes to move between the two
limbs of the magnet, and sometimes to be repelled
from between them according to the sense of the
current in the surrounding coil. He and Ampere
both attributed the effect to temporary magnetism
conferred upon the copper ring. Ampere himself was
*See a paper by the author in the Philosophical Magazine for June,
1895, entitled " Note on a Neglected Experiment of Ampere,"
lOG iMICHAEL FARADAY.
at the tiiue disposed to attribute it to the possible
])resence of a httle iron as an impurity in the copper.
There are, however, some discrepancies in the three
pubUshed versions of the story. According to
Eecquerel, Ampere had by 1825 satisfied himself of
the non-existence of induction currents.
Quite independently, the question of the possibility
of creating currents by magnets was raised by another
discovery, that of the so-called "magnetism of rotation."
In 1^>24 Arago had observed that a tine magnetic
compass constructed for him by Gainbey, having the
needle suspended in a cell, the base of which Avas a
plate of piu'e copper, Avas thereby damped in its
oscillations, and instead of making two or three
hundred vibrations before it came to rest, as would be
the case in the open air, executed only three or four
of rapidly decreasing amplitude."^ In vain did Dumas
at the request of Arago analyse the copper, in the
supposition that iron might be present. Inquiry
compelled the conclusion that some other explanation
must be sought. And, reasoning irom the apparent
action of stationary copper in bringing a moving
magnetic needle to rest, he conjectured that a moving
mass of copper might produce motion in a stationary
magnetic needle. Accordingly he set into revolution,
beneath a compass needle, a flat disc of copper, and
found that, even when a sheet of card or glass Avas
interposed to cut off all air-currents, the needle tended
to follow the moA^ing copper disc, turning as if dragged
^' Compare Dumas, " Kloge Histoiique de Michel Faniday," p. xxxiii.,
who gives the above statement. Arago's own account to the Acadimk
differs slightly.
A PUZZLING EXPERIMENT. 107
by some invisible influence. Tr) the suggestion that
mere rotation conferred upon copper a sort of
temporary magnetism Arago listened with some
impatience. All theories proposed to account for the
phenomenon he discredited, even though emanating
from the great mathematician Poisson. He held
his j udgment in absolute suspense. Babbage and
Herschel measured the amount of retarding force
exerted on the needle by different materials, and
found the most eftective to be silver and copper
(which are the two best conductors of electricity),
after them gold and zinc, whilst lead, mercury, and
bismuth were inferior in power. The next year the
same experimenters announced the successful inversion
of Arago's experiment ; for by spinning the magnet
underneath a pivoted copper disc they caused the
latter to rotate briskly. They also made the notable
observation that if slits are cut radially in the copper
disc they diminish its tendency to be dragged by the
spinning magnet. Sturgeon showed that the damp-
ing effect of a moving copper disc was diminished by
the presence of a second magnet pole of contrary kind
placed beside the first. All these things were most
suggestive of the real explanation. It clearly had
something to do with the electric conductivity of
the metal disc, and therefore with electric currents.
Sturgeon five years later came very near to the
explanation : after repeating the experiments he con-
cluded that the effect was an electric disturbance in
the copper disc, " a kind of reaction to that which
takes place in electromagnetism."
Faraday knew of all the discussions which had
108
MICHAEL FAUADAV.
arisen respecting Arago's rotations
They may have
been the cause of his unsuccessful attempts of 1824
and 1825. In April, 1828, for the fourth time he
tried to discover the currents which he was convinced
must be producible by the magnet, and for the fourth
time without result. The cause of failure A^^as that
both magnet and coil were at rest.
Fig. 4.
The summer of 1831 witnessed him for the fifth
time making the attaclv on the problem thus per-
sistently before him. In his laboratory note-book he
heads the research " Experiments on the production
of electricity from magnetism." The following ex-
cellent summary of the laboratory notes is taken from
Bence Jones's " Life and Letters " : —
I have had an iron ring made (soft iron), iron round and
gths of an inch thick, and ring six inches in external diameter.
Wound many coils of copper round, one half of the coils being
separated by twine and calico ; there were three lengths of
SUCCESS IN sioriT. 109
wire, each about twenty-four feet long, and they could be con-
nected as one length, or used as separate lengths. By trials
with a trough each was insulated from the other. Will call
this side of the ring a. On the other side, but separated by
an interval, was wound wire in two pieces, together amounting
to about sixty feet in length, the direction being as with the
former coils. This side call b. ^
Charged a battery of ten pairs of i)lates four inches square.
Made the coil on e side one coil, and connected its extremities
by a copper wire passing to a distance, and just over a magnetic
needle (three feet from wire ring), then connected the ends of
one of the pieces on a side with battery : immediately a
sensible effect on needle. It oscillated and settled at last in
original position. On breaking connection of a side with
battery, again a disturbance of the needle.
In the seventeenth paragraph, written on the 30th
ot August, he says, " May not these transient efi'ects be
connected with causes of difierence betAveen power of
metals at rest and in motion in Arago's experiments?"
After this he prepared fresh apparatus.
As was his manner, he wrote off to one of his
friends a letter tehing what he was at work upon.
On this occasion the recipient of his confidences was
his friend PhilHps : —
[Michael Faraday to Richard Phillips.']
Royal Institution.
My dear Phillips, Sept. 23, 1831.
I write now, though it may be some time before I
send my letter, but that is of no great consequence. I received
* This ring Faraday ia represented as holding in his hand in the
heautiful marble statue by Foley which stands in the Entrance HaU
of the Royal Institution. The ring itself is still preserved at the
Royal Institution amongst the Faraday relics. The accompanying
cut (Fig. 4) is facsimiled from Faraday's own sketch in his laboratory
note -book.
110 MICHAEL FARADAY.
your letter to Dr. Reid and read it on the coach going to
Hastings, where I have been i)assing a few weeks, and I fancy
n)y fellow passengers thought 1 had got something very droll
in hand ; they sometimes started at my sudden bursts, especially
when I had the moment before been very grave and serious
amongst the proportions. As you say in the letter there are
some new facts and they are always of value ; otherwise I
should have thought you had taken more trouble than the
matter deserved. Your quotation from ]joyIe has nevertheless
gieat force in it.
I shall send with this a little thing in your own way " On the
Alleged decline of science in England." It is written by Dr.
^foU of Utrecht, whose name may be mentioned in conversa-
tion though it is not printed in the pamphlet. I understand
the view taken by Moll is not at all agreeable to some. "I do
not know what business Moll had tointerfere with our scientific
disputes " is however the strongest observation I have heard of
in reply.
I do not think I thanked you for your last Pharmacopoeia-
I do so now very heartily. I shall detain this letter a few days
that I may send a coui)le of my papers [i.e. a paper and appendix)
with it, for though not chemical I think you will like to have
them. I am busy just now again on Electro-Magnetism, and
think I have got hold of a good thing, but can't say; it may be
a weed instead of a fish that after all my labour I may at last
pull up. I think I know why metals are magnetic when in
motion though not (generally) when at rest.
We think about you all very much at times, and talk over
affairs of Nelson Square, but I think we dwell more upon the
illnesses and nursings and upon the sudden calls and chats
rather than the regular parties. Pray remember us both to
Mrs. Phillips and the damsils — I hope the word is not too
familiar.
I am Dear Phillips,
Most Truly Yours,
P. Phillips, Esq., M. Faraday.
&c., &c., iJcc.
TEN DAYS OF SPLENDID WORK.
Ill
September 24 was the third day of his experiments.
Ho began (paragraph 21) by trying to find the eh'oct of
one helix of wire, carrying the vohaic current of ten
pairs of pkites, upon another wire connected with a
galvanometer. " No induction sensible." Longer and
different metallic helices (paragraph 22) showed no
effect ; so he gave up those experiments for that day,
and tried the effects of bar magnets in-
stead of the ring magnet he had used <ni
the first day.
In paragraph S'A he says ; — l^'tt
All iron cylinder had a helix MOund on it.
The ends of the wires of the helix were connected
with the indicating helix at a distance by co])per
wire. Then the iron placed between the poley of
bar magnets as in accom].)anying figure (Fig. 5).
Every time the magnetic contact at n or s was
made or broken, theie was magnetic motion at
the indicating helix — the effect being, as in
former cases, not permanent, but a mere mo-
mentary push or piilL But if the electric com-
munication (i.e. by the copper wire) was broken,
then the disjunction and contacts produced no effect whatever.
Hence here distinct conversion of magnetism into electricity.
The fourth day of work was October 1. Para-
graphs 8(i, 87, and 38 describe the discovery of
induced voltaic currents : —
3G. A battery of ten troughs, each of ten pairs of plates
four inches square, charged with good mixture of sulphuric
and nitric acid, and the following experiments juade with it in
the following order.
37. One of the coils (of a helix of copper wire 203 feet long)
waa connected with the fiat helix, and the other (coil of same
Fig. 5.
112 MICHAEL FARADAY.
length round sMme block of wood) with the poles of the battery
(it having been found that there was no metallic contact
between the two) ; the magnetic needle at the indicating fiat
helix was affected, but so little as to be hardly sensible.
38. In place of the indicating helix, our galvanometer was
used, and then a sudden jerk was perceived when the battery
communication was made and broken^ but it was so slight as
to be scarcely visible. It was one way when made, the other
when broken, and the needle took up its natural position at
intermediate times-
Hence there is an inducing effect without the presence of
iron, Imt it is either very weak or else so sudden as not to
have time to move the needle. I rather suspect it is the latter.
The fifth day of experiment was October 17.
Paragraph 57 describes the discovery of the produc-
tion of electricity by the approximation of a magnet
to a wire : —
A cylindrical bar magnet three-quarters of an inch in
diameter, and eight inches and a half in length, bad one end
just inserted into the end of the helix cylinder (220 feet long) ;
then it was quickly thrust in the whole length, and the galvan-
ometer needle moved ; then pulled out, and again the needle
moved, but in the opposite direction. This effect was repeated
every time the magnet was put in or out, and therefore a wave
of electricity was so produced from viere approximation of a
magnet^ and not from its formation in situ.
\ The cause of all the earlier failures was, then, that
] both magnet and coil were at rest. The magnet might
,' lie in or near the coil for a century and cause no effect.
But "while moving towards the coil, or from it, or
by spinning near it, electric currents were at once
induced.
The ninth day of his experiments was October 28,
SUCCESS AND ITS SECUET. IKi
and this day he " made a copjjer disc turn round
between the poles of the great horse-shoe magnet of
the Ro3'al Society. The axis and edge of the disc
were connected with a !.ailvanometer. The needle
o
moved as the disc turned," The next day that he
made experiments, November 4, he found " that a
copper wire one-eighth of an inch drawn between the
poles and conductors produced the effect." In his
paper, when describing the exj^eriment, he speaks of
the metal "cutting" the magnetic curves, and in a
note to his paper he says, " By magnetic curves I
mean lines of magnetic forces which would be depicted
by iron tilings."
We here come upon those ''lines of force" which
pla3^ed so important a part in these and many of
Faraday's later investigations. They were known
before Faraday's tinae — had, in fact, been known for
two hundred years. Descartes had seen in them
evidence for his hypothetical vortices. Musschen-
broek had mapped them. But it was reserved to
Faraday to point out their true significance. To the
very end of his life he continued to speculate and
experiment upon them.
All this splendid Avork had occupied but a brief
ten days. Then he rearranged the facts which he had
thus harvested, and wrote them out in corrected form
as the first series of his " Experimental Researches in
Electricity." The memoir was read to the Royal
Society on November 24, 1831, though it did not
appear in printed form until January, 1832 — a dela}^
which gave rise to serious misunderstandings. The
paper having been read, he went away to Brighton to
I
114 MICHAEL FARADAY.
take a holiday, and in the exuberance of his heart-
penned the following letter* to Phillips: —
[M. Faraday to E. FhUlips.']
Brighton : November 29, 1831.
Dear Phillips, — For once in my life I am able to sit down
and write to yon without feeling that my time is so little that
my letter must of necessity be a short one and accordingly I
have taken an extra large sheet of paper intending to fill it
with news and yet as to news I have none for I withdraw
more and more from Society, and all I have to say is about
myself.
But how are you getting on^ are you comfortable'? and how
does Mrs. Phillips do ; and the girls ? Bad correspondant as I
am, I think you owe me a letter and as in the course of half an
hour you will be doubly in my debt pray write us, and let us
know all about you. Mrs. Faraday wishes me not to forget to
put her kind remembrances to you and Mrs. Phillips in my
letter.
To-morrow is St. Andrew's day,t but we shall be here until
Thursday. I have made arrangements to be out of tlie Council
and care little for the rest although I should as a matter of
curiosity have liked to see the Duke in the chair on such an
occasion.
AVe are here to refresh. I have been working and writing
a paper and that always knocks me up in health, but now I
feel well again and able to pursue my subject and now I will
tell you what it is about. The title will be, I think, Experi-
mental Researches in Electricity: §I. On the induction
of electric currents. §11. On the evolution of Electricity from
rnagnetis)n,. § III. On a Nev) electrical condition of matter.
§ IV. On Ararjo's magnetic phenomcyia. There is a bill of fare
for you ; and what is more I hope it will not disappoint you.
*" Now in the possession of the author, to whom it was given by
his kinswoman Lady Wilson, youngest daughter of Richard Phillips.
f The day of the Annual Meeting and election of Council of the
Koyal Society. - - ~-.
TKE PITH OK THE IHSCOVEKY. 115
Nuw the [lith of ail this I must give you very biieldy ; the
demonstrations you shall have in the paper when printed —
§ I. When ;in electric current is i)assed through one of two
liarallel wires it causes at Hrst a current in tlie same direction*
through the other, but this induced current does not last a
mon^ent, notwithstanding the inducing current (from the
Voltaic battery) is continued all seems unchanged except tliat
the principal current continues its course, but when the current
is stopped then a return cm-rent occurs in the wire under
induction of about the same intensity and momentary duration
but in the opposite direction to that first found. Electricity
in currents therefore exerts an inductive action like ordinary
electricity but subject to peculiar laws : the effects are a current
in the same direction when the induction is established : a
reverse current when the induction ceases and a pecxdiar state
in the interim. Comnum electricity probably does the same
thing but as it is at present impossible to separate the be-
ginning and the end of a spark or discharge from each other,
all the effects are simultaneous and neutralise each other—
§11. Then I found that magnets would induce just like
voltaic currents and by bringing helices and wires and jackets
up to the poles of magnets, electrical currents were produced,
in tliem these currents being able to deflect the galvanometer,
or to make, by means of the helix, magnetic needles, or in one
case even to give a spark. Hence the evolution of electricity
from magnetism. The cunents were not permanent, they
ceased the moment the wires ceased to approach the magnet
because the new and apjiarently quiescent state was assumed
just as in the case of the induction of currents. But when the
magnet was removed, and its induction therefore ceased, the
return currents appeared as before. These two kinds of
induction I have distinguished by the terms Volta-electric and
Magneto-electric induction. Their identity of action and
* This is a slip in the description; the momentary current in-
duced in the secondary wire on making the current in the primary
ia inverse : it is tjucceeded by a momentary direct current when the
primary current is stopped.
116 MICHAEL FARADAY.
results is, I think, a very powerful proof of the truth of M.
Ampere's theory of magnetism.
§ III. The new electrical condition which intervenes by
induction between the beginning and end of the inducing
current gives rise to some very curious results. It explains
why chemical action or other results of electricity have never
been as yet obtained in trials Avith the magnet, hi fact, the
currents have no sensible duration. I believe it will explain
perfectly the transference of dewenU between the poles of the
pile in decomposition but this part of the subject I have
reserved until the present experiments are completed and it is
so analogous, in some of its effects to those of Hitter's secondary
piles, De la Jiive and Van Beck's peculiar properties of the
poles of a voltaic pile, that I should not wonder if they all
proved ultimately to depend on this state. The condition of
matter I have dignified by the term Electrotonic^ The Electro-
tonic State. What do you think of that^ Am I not a bold
man, ignorant as I am, to coin words but I have consulted the
scholars," and now for § IV. The new state has enabled me
to make out and explain all Arago's phenomena of the rotating
magnet or copper plate, I believe, perfectly ; but as great
names are concerned Arago, Babbage, Herschel, tfec, and as I
have to differ from them, I have spoken with that modesty
which you so well know you and I and John Frost f have in
common, and for which the world so justly commends us. I
am even half afraid to tell you what it is. You will think I
am hoaxing you, or else in your compassion you may conclude
I am deceiving myself. However, you need do neither, but
had better laugh, as I did most heartily when I found that it
was neither attraction nor rei^ulsion, but just one of my old
rotations in a new form. I cannot explain to you all the
actions, which are very curious ; but in conserj^uence of the
" This doubtless refers to Whewell, of Cambridge, whom he was
in the habit of consulting on questions of nomenelature.
t A man of fashion who had, without any claim to distinction,
wormed himself into scientific society, posed as a savant, and had
delivered a high-flown oration on botany at the Royal Institution.
A JUBILANT EPISTLE. 117
electrotonic state being assumed and lost as the parts of the
plate Avhirl under the pole, and in conseiiuence of magneto-
electric induction, currents of electricity are formed in the
direction of the radii ; continuing, for simple reasons, as long as
the motion continues, but ceasing when that ceases. Hence
the wonder is explained that the metal has powers on the
magnet wlien moving, but not Avhen at rest. Hence is also
explained the effect which Arago observed, and which made
him contradict Eabbage and Her.schel, and say the power was
repulsive ; but, as a whole, it is really tangential. It is quite
comfortable to me to hnd that experiment need not quail
before mathematics, but is quite competent to rival it in
discovery ; and I am amused to find that what the high mathe-
maticians have announced as the essential condition to the
rotation — namely, that tione is required — has so little founda-
tion, that if the time could by possibility be anticipated instead
of being required — i.e. if the currents could be formed before
the magnet came over the place instead of after — the effect
would equally ensue. Adieu, dear Phillips.
Excuse this egotistical letter from yours very faithfully,
M. Faraday.
The second section shows that Faraday had dis-
covered the cause of all the previous failures to evoke
electric currents in wires by means of a magnet : it
required relative motion. What the magnet at rest
fails to do, the magnet in motion accomplishes. This
crucial point is admirably commemorated in the
following hnpromptu given by Mr. Herbert Mayo to
Sir Charles Wheatstone : —
Around the magnet Faraday
Was sure that Volta's lightnings play :
But how to draw them from the wire ?
He took a lesson from the heart :
'Tis when we meet, 'tis when we part,
Breaks forth the electric fire.
lis MICHAEL FAUADAY.
Faraday's holiday was brief; by December 5 he
was again at work on his researches. He re-observed
the directions of the induced currents about which, as
the sHp in his letter to ThiUips shows, his mind was
in some doubt. Then on December J4th conies the
entry: — "Tried the effects of terrestrial magnetism in
evolving electricity. Obtained beautiful results."
" The helix had the soft iron cylinder (freed from
magnetism by a full red heat and coolmg slowly) put
into it, and it was then connected with the galvan-
ometer by wires eight foot long ; then inverted the
bar and helix, and immediately the needle moved ;
inverted it again, the needle moved back; and, by
repeating the motion with the oscillations of the
needle, made the latter vibrate 180"^', or more."
The same day he " made Arago's experiment with
the earth magnet, only no magnet used, but the plate
put horizontal and rotated. The effect at the needle
Avas slight but very distinct. . . . . Hence Arago's
plate a new electrical machine."
When we compare these manuscript notes, record-
ing the experiments in the order in which they were
made with the published account of them in the
*' Experimental Researches," we find many of them
transcribed almost verbatim. But there is a difference
in the order of their arrangement. In point of time
the experiments on the evolution of electricity from
magnetism, beginning with the ring (p. 108), preceded
those on the induction of a current by another cur-
rent. In the printed " Researches " the experiments
on the induction of currents are put firsts with an
introductory paragraph on the general phenomenon
POINTS IN THE DISCOVERY. 119
of induction."^ Faraday'vS habit of working up an
experiment — whether successful or unsuccessful — by
increasing the power to the maximum available is
illustrated in the course of the experiments on the
iron ring. At first he used a battery of ten pairs
of plates four inches square. Then, having been
eminently successful in producing deflexions of his
galvanometer, he increased the battery to one hundred
pairs of plates, with the result that when contact
was completed or broken in the primary circuit the
impulse on the galvanometer in the secondary circuit
was so great as to make the needle spin round rapidly
foiu* or five times before its motion was reduced to a
mere oscillation. Then he removed the galvanometer
and fixed small pencils of charcoal to the ends of the
secondary helix ; and to his great joy perceived a
minute spark between the lightly touching charcoal
points whenever the contact of the battery to the
primary helix was completed. This was the first
* The use of this term, as distinguished from, production, to dis-
tinguish hetween the primary generation of a current in a voltaic cell,
a thermopile, or a friction-machine, hy chemical or molecular action,
and its indirect production without contact or communication of any
material sort, as by motion of a wire near a magnet or by secondary
influence from a neighbouring primary current while that current is
varying in strength or proximity, is exceedingly significant. Fara-
day's own meaning in adopting it is best grasped by referring top. 1
of the " Experimental Researches " : —
" On the /jidHcfiou of Electric Currents." .... The general term inrfuciioH
which, as it has been received into scientific' lauguag'e, may also, with propriety,
be used to express the power which electrical currents may possess of inducing any
particular state upon matter in their immediate neigliboiirhood. ... I projiose
to call this action of the current from the voltaic battery uo?(a-eiec(ric mdnc^ioTi . . .
but as a distinction in language is still necessary, I propose to call the agency thus
exerted by ordinary magnets viagneto-elcctric or magnc-eUctric induction.
120 MICHAEL FARADAY.
transformer, for the first time set — on a small scale
— to produce a tiny electric light. The spark he
regarded as a precious indication that what he was
producing really was an electric current. Using the
great compound steel magnet of the Royal Society
(constructed by Dr. Gowin Knight) at Christie's house
at Woolwich he had, as narrated above, also obtained
a spark from the induced current. For some time he
failed to obtain either physiological or chemical effects.
But upon repeating the experiments more at leisure
at the Royal Institution, with Daniell's armed load-
stone capable of lifting thirty pounds, a frog was
found to be convulsed very strongly each time mag-
netic contact between the magnet and the iron core
of the experimental coil was made or broken.
The absence of evidence as to chemical action
seemed still to disquiet him. He wanted to be sure
that his induced currents would do everything that
ordinary voltaic currents would do. Failing the final
proof from chemical action, he rested the case on the
other identical properties. " But an agent," he says,
" which is conducted along metallic wires in the
manner described ; which, Avhilst so passing, possesses
the peculiar magnetic actions and force of a current
of electricity : which can agitate and convulse the
limbs of a frog ; and which, finally, can produce a
spark by its discharge through charcoal, can only be
electricity. As all the effects can be produced by
ferruginous electro-magnets, there is no doubt that
arrangements like the magnets of Professors iloll,
Henr}^, Ten Eyke, and others, in which as many as
two thousand pounds have been lifted, may be used
A NEW ELECTHICAL MACHINE.
121
for these experiments ; in which case not only a
brighter spark may be obtained, but wires also ignited,
and as the ciiri'ents can pass liquids, chemical action
be produced. These effects are still more likely to be
obtained when the magneto-electric arrangements, to
be explained in the fourth section, are excited by the
powers of such apparatus." The apparatus described
in the fourth section comprised several forms of
Fig. (>. {FAcrsiMiLE OF Okigin'al Sketch.)
magneto-electric machines, that is to say, primitive
kinds of dynamos. Having in his mind the pheno-
menon discovered by Arago, and the experiments of
Babbasre and Herschel on the so-called mao-netism of
rotation, he followed up the idea that these effects
might be due to induced currents eddying round in
the copper disc. No sooner had he obtained electricity
from magnets than he attempted to make Arago's
experiment a new source of electricity, and, as he
himself says, " did not despair " " of being able to
construct a new electrical machine."
122 MICHAEL FARADAY.
The " new electrical machine " was an exceedingly
simple contrivance. A disc of copper, twelve inches
in diameter (Fig. 6), and about one-tifth of an inch in
thickness, fixed upon a brass axle, was mounted in
frames, so as to allow of revolution, its edge being at
the same time introduced between the magnetic poles
of a large compound permanent magnet, the poles
being about half an inch apart. "^^ The magnet first
used was the historical magnet of Gfjwin Knight.
The edge of the plate was well amalgamated, for the
purpose of obtaining a good but movable contact, and
a part round the axle was also prepared in a similar
manner. Conducting strips of copper and lead, to
serve as electric collectors, were prepared, so as to be
placed in contact with the edge of the copper disc ;
one of these was held by hand to touch the edge of
the disc between the magnet poles. The wires from a
galvanometer were connected, the one to the collect-
ing-strip, the other to the brass axle ; then on revolv-
ing the disc a deflexion of the galvanometer was
obtained, which was reversed in direction when the
direction of the rotation Avas reversed. " Here, there-
fore, was demonstrated the production of a permanent
current of electricity by ordinary magnets." These
effects were also obtained from the poles of electro-
magnets, and from copper helices without iron cores.
Several other forms of magneto-electric machines were
tried by Faraday.
i> til
'Experimental Researches,'* i. 25, art. 85, This copper disc is
still preserved at the Royal Institution. It was shown in action by
the author of this work, at a lecture at the Koyal Institution delivered
April 11th, 1891. Fig. 6 is reproduced in facsimile from Faraday's
laboratory note-book.
NEW FORMS OV APPARATUS.
123
In onc,"^' a liat ring of twelve inches' external
diameter, and one inch broad, was cut from a thick
copper plate, and mounted to revolve between the
poles of the magnet, two conductors being applied to
make rubbmg contact at the inner and outer edge at
the part which passed between the magnetic poles.
In another,t a disc of copper, one-fifth of an inch
thick and only fi inch in diameter (Fig. 7), was amalga-
mated at the edge, and mounted on a copper axle. A
square piece of sheet metal had a circular hole cut in
it, into Avhich the disc fitted loosely : a little mercury
completed connnunication between the disc and its
surrounding ring. The latter was connected by wire
to a o-alvanometer ; the other wire beine* connected
from the instrument to the end of tlie axle. Upon
rotating the disc in a horizontal plane, currents were
obtained, though the earth was the only magnet
employed.
Faraday also proposed a multiple machinej having
several discs, metallically connected alternately at the
* "Experinirntal pLesearchcs," i. art. 13-3.
t Jb., art. 15,3. + lb., ait. lo
124
MICHAEL FARADAY.
edges and centres by means of mercury, which were
then to be revolved alternately in opposite directions,
In another apparatus,* a copper cylinder (Fig. 8),
closed at one extremity, was put over a magnet, one
half of which it enclosed like a cap, and to which it
was attached without making metalhc contact. The
arrangement was then floated upright in a narrow jar
Fig. 8.
of mercury, so that the lower edge of the copper cap
touched the fluid. On rotating the magnet and its
attached cap, a current was sent through wires from
the mercury to the top of the copper cap. In another
apparatus, t still preserved at the Royal Institution, a
cylindrical bar magnet, half immersed in mercury,
was made to rotate, and generated a current, its own
metal serving as a conductor. In another form,:[: the
cylindrical magnet was rotated horizontally about its
own axis, and was found to generate currents which
* lb,, art. 219.
t "Experimental Researches," i. art. 220.
X lb., art. 222.
AN EARTH-INDUCTOR.
125
flowed from the middle to the ends, or vice versa,
accordmg to the rotation. The description of these
new electrical machines is concluded with the follow-
ing pregnant words ; —
I have rather, however, been desirou-s of discovering new
facts and relations dependent on magneto-electric induction,
than of exalting the force of those already obtained ; being
assured that the latter would find their full development
hereafter.
Fig. 9.
In yet another naachine (Fig. 9), constructed by
Faraday some time later * a simple rectangle of copper
wire IV, attached to a frame, was rotated about a
horizontal axis placed east and west, and generated
alternate currents, which coidd be collected by a
simple comnuitator c.
Within a few months machines on the principle of
magneto-induction had been devised by Dal Negro,
and by Pixii. In the latter's apparatus a steel horse-
shoe magnet, with its poles upwards, was caused to
rotate about a vertical shaft, inducing alternating
currents in a pair of bobbins fixed above it, and
'^ lb., iii. art 3192.
126 MICHAEL fai:a]>av.
provided with a horseshoe core of soft iron. Later, in
1832, Pixii produced, at the suggestion of Ampere,^ a
second machine, provided with mercury cup con-
nections to rectify the alternations of the current.
One of these machines was shown at the British
Association meeting at Oxford in the same year
(p. 64).
The idea developed in the third part of this
research was intensely original and suggestive. Fara-
day's own statement is as follows: —
Whilst the wire i.s subject to either volta-electric or magneto-
electric induction, it appears to be in a peculiar state ; for it
resists the formation ot an electrical current in it, whereas, if
left in its common condition, such a current would be produced ;
and when left uninfluenced it has the power of originating a
current, a power which the wire does not possess under common
circumstances. This electrical condition of matter has not
hitherto l»een recognised, but it probably exerts a very im-
p>ortant influence in many, if not most, of the phenomena
produced by currents of electricity. For reasons which will
immediately appear, I have, after advising with several learned
friends, ventured to designate it as the electrotoiiic state.
This peculiar condition shows no known electrical effects
whilst it continues ; nor have I yet been able to discover any
peculiar powers exerted or properties possessed by matter
whilst retained in this state.
This state is altogether the effect of the induction exerted,
and ceases as soon as the inductive force is removed
The state appears to be instantly assumed, requiring hardly
a sensible portion of time for that [)urpose In all
those cases where the helices or wires are advanced towards
or taken from the magnet, the direct or inverted current of
* "Ann. Chim. Phys.," U. 76, 1832.
THE ELECTKOTONKJ STATE. 127
induced electricity continues for the time occupied in the
advance or recession ; for the electro-tonic state is rising to a
higher or falling to a lower degree during that time, and the
change is accompanied by its corresponding evolution of
electricity ; but these form no objections to the 0[union that
the electro-tonic state is instantly assumed.
This peculiar state appears to be a state of tension, and may
be considered as erjuivnlent to a current of electricity, at least
equal to that produced either when the condition is induced
or destroyed.
Faraday further supposed that the formation of
this state in the neii^fhbourhood of a coil would
exert a reaction upon the original current, giving
rise to a retardation of it ; but he "was unable at
the time to ascertain experimentally whether this Avas
so. He even looked — though also unsuccessfully —
for a self-induced return current from a conductor of
copper through which a strong current was led and
then suddenly interrupted, the expected current of
reaction being "due to the discharge of its supposed
electrotonic state."
If we would understand the rather obscure language
in which this idea of an electrotonic state is couched,
we must try to put ourselves back to the epoch
Avhen it was written. At that date the only ideas
which had been formulated to explain magnetic and
electric attractions and repulsions were founded upon
the notion of action at a distance. Michell had
propounded the view that the electric and magnetic
forces vary, like gravity, according to a law of the
inverse squares of the distances. Coulomb, in a series
of experiments requiring extraordinary patience as
well as delicacy of manipulation, had shown — by an
12S MICHAEL FARADAY.
application of Micbell's torsion balance — that in par-
ticular cases where the electric changes are concen-
trated on small spheres, or where the niagnetic poles
are small, so as to act as mere points, this law — which
is essentialh' a i^eometric law of point-action — is
ajDproximately fultilled. The mathematicians, Laplace
and Poisson at tlieir head, had seized on this demonstra-
lion and had elaborated their mathematical theories.
Before them, thoncdi the research lav for a century
unpublished, Cavendish had shown that the onl}' law
of force as between one element of an electric chars^e
and another compatible with a charge being in
equilibrium was the law of inverse squares. But in
all these mathematical reasonins^s one thins^ had been
quite left out of sight — namely, the possible properties
of the intervening medium. Faraday, to whom the
idea of mere action at a distance Avas abhorrent, if not
unthinkable, conceived of all these forces of attraction
and repulsion as efiects taking place by something
going on in. fl/e intervening medium, as effects
propagated from point to point continuously through
space. In his earher work on the electromagnetic
rotations he had gro^vn to regard the space around
the conducting wire as being affected by the so-called
current : and the space about the poles of a magnet
he knew to be traversed by curved magnetic lines,
invisible indeed, but real, needing only the simplest of
expedients — the sprinkling of iron fihngs — to reveal
their existence and trend. When therefore he found
that these new effects of the induction of one electric
cun-ent by another could likewise cross an intervening
space, whether empty or filled with material bodies^
A SPAP.K FROM A MAGNET. 1*29
he instinctively songlit to ascribe this propagation
of the effect, to a property or state of the niediuni.
And linding that state to be different from any state
previously kno"\yn, different from the state existing
bet^veen f\vo magnets at rest or bet\veen two stationary
electric charges, he foUo^ved the entirely philosophical
course of exploring its properties and of denoting it
by a name which he deemed appropriate. As we
shall see. this idea of an electrotonic state recurred in
his later researches with new and important conno-
tations.
He was soon at work again, as we have seen.
He experimented, in Januar}', 1832, on the currents
produced by the earth's rotation — on the 10th at the
round pond in Kensington Gardens, and on the 12th
and loth at Waterloo Bridge.
'■ This evening." he writes in his notebook under
date Februar}' ^, "" at Woolwich, experinienting with
magnet,^ and for the lirst time got the magnetic spark
myself. Connected ends of a helix into two general
ends, and then crossed the wires in such a way that a
blow at a h would open them a little [Fig. 10]. Then
* The great magnet of the RL-yal S>:ieiety. whieh was at this time
lent to AEr. Christie.
J
130 MICHAEL FARADAY.
bringing a. h against the poles of a magnet, the ends
■^vere disjoined, and bright sparks resnUed."
From succeeding "with a steel magnet it was biit a
short step to succeed when a natural loadstone was
used. The next day we find this entry : — " At home
succeeded beautifully with Mr. Daniells magnet.
Amalgamation of wires very needful. This is a
natural loadstone, and perhaps the first used for the
spark."
He sent to the Ro3-al Society an account of these
and the earlier experiments : his paper on terrestrial
magneto-electric induction, and on the force and
direction of magneto-electric induction, received the
distinction of being read as the Bakerian lecture of
the year.
The following suramar}* of this second paper is
from the pen of Professor T3'ndaU : —
He placed a bar of iron in a coil of wire, and lifting the
bar into the direction of the dipping needle, he excited by this
action a current in the coil. On reversing the bar, a current
in the opposite direction rushed through the wire. The same
effect was produced, ^Then, on holding the helix in the line of
dip, a bar of iron was thrust into it. Here, however, the earth
acted on the coil through the intermediation of the bar of iron.
He abandoned the bar, and simply* set a copper plate spinning
in a horizontal plane ; he knew that the earth's lines of
magnetic force then crossed the plate at an angle of about 70'^.
\Vhen the plate spun round, the lines of force were intersected
and induced currents generated, which produced their proper
effect when carried from the plate to the galvanometer.
" When the plate was in the magnetic meridian, or in any-
other plane coinciding with the magnetic dip, then it^ rotation
produced no effect upon the galvanometer."
TYNDALL's SaMMARY. 131
At the suggestion of a mind fruitful in suggestions of a
profound and philosophic character — I mean that of Sir John
Herschel— Mr. Barlow, of Woolwich, had experimented with a
rotating iron shell. Mr. Christie had also performed an
elaborate series of experiments on a rotating iron disc. Both
of them had found that when in rotation the body exercised a
])eculiar action upon the magnetic needle, deflecting it in a
manner which Avas not observed during quiescence ; but
neither of them was aware at the time of the agent which
produced this extraordinary deflection. They ascribed it to
some change in the magnetism of the iron shell and disc.
But Faraday at once saw that his induced currents must
come into play here, and he immediately obtained them from
an iron disc. With a hollow brass ball, moreover, he produced
the effects obtained by Mr. Barlow. Iron was in no way
necessary ; the only condition of success was that the rotating
body should be of a character to admit of the formation of
currents in its substance ; it must, in other Avords, be a con-
ductor of electricity. The higher the conducting power, the
more copious Avere the currents. He now passes from his little
brass globe to the globe of the earth. He plays like a magician
with the earth's magnetism. He sees the invisible lines along
which its magnetic action is exerted, and, sAveei)ing his wand
across these lines, he evokes this new power. Placing a simple
loop of wire round a magnetic needle, he bends its upper
portion to the west ; the north pole of the needle immediately
swerves to the east ; he bends his loop to the east, and the
north pole moves to the west. Suspending a common bar
magnet in a vertical position, he causes it to spin round its
own axis. Its pole being connected with one end of a galvano-
meter wire, and its equator witli the other end, electricity
rushes round the galvanometer from the rotating magnet. He
remarks upon the *' singular -mJependtn-ce " of the magnetism
and the body of the magnet which carries it. The steel behaves
as if it were isolated from its own magnetism.
And then his thoughts suddenly widen, and he asks himself
whether the rotating earth does not generate induced currents
as it turns round its axis from west to east. In his experiment
182 MICHAEL FARADAY.
with the twirling magnet the galvanometer wire remained at
rest ; one portion of the circuit was in motion relatively to
another po)-tion. But in the case of the twirling planet the
galvanometp.r wire would necessarily be carried along with the
earth ; there would be no relative motion. What must be the
consequence? Take the case of a telegrapli wire with its two
terminal plates dipped into the earth, and sup^tose the wire to
lie in the magnetic meridian. The ground underneath the
wire is influenced, like the wire itself, by the earth's rotation ;
if a current from south to north be generated in the wire, a
similar current from south to north would be generated in the
earth under the wire ; these currents would run against the
same terminal plate, and thus neutralise each other.
This inference appears iuevitable, but his profound vision
perceived its possible invalidity. He saw that it was at least
possible that the difference of conducting power between the
earth and the wire might give one an advantage over the other,
and that thus a residual or differential current might be
obtained. He combined wires of different materials, and
caused them to act in opposition to each other, but found the
combination ineffectual. The more copious flow in the better
conductor was exactly counterbalanced by the resistance of the
worst. Still, though experiment Avas thus emphatic, he would
clear his mind of all discomfort by operating on the earth
itself. He went to the round lake near Kensington Palace,
and stretched 480 feet of copper wire, north and south, over
the lake, causing plates soldered to the wire at its ends to dip
into the water. The copper wire was severed at the middle,
and the severed ends connected with a galvanometer. No
effect whatever was observed. But though quiescent water
gave no effect, moving water might. He therefore worked at
Waterloo Bridge for three days, during the ebb and flow of the
tide, but without any satisfactory result. Still he urges,
" Theoretically it seems a necessary consequence, that where
water is flowing there electric currents should be formed. If a
line be imagined passing from Dover to Calais through the sea
and returning through the land, beneath the water, to Dover,
it traces out a circuit of conducting matter, one part of which,
THE LAW OF INDUr'TlON. 133
when the water moves up or down the Channel, is cutting the
magnetic curves of the earth, whilst the other is relatively at
rest There is every reason to believe that currents
do run in the general direction of the circuit described, either
one way or the other, according as the passage of the waters is
up or down the Channel." This w^as written before the sub-
marine cable was thought of, and he once informed me that
actual observation upon that cable had been found to be in
accordance x\ith his theoretic deduction.
It may here be apposite to discuss a fundamental
question raised in these researches. In Faraday's
.\
Fig. U.
mind there arose the conviction of a connection be-
tween the induction of currents by magnets and the
magnetic lines which invisibly fill all the space in the
neighbourhood of the magnet. That relation he dis-
covered and announced in the following terms : —
" The relation which holds between the magnetic
pole, the moving wire or metal, and the direction of
the current evolved — i.e. the la%v which governs the
evolution of electricity by magneto- electric induction,
is very simple, though rather difficult to express. If
in Fig. 11^ p N represent a horizontal wire passing by
a marked [i.e. ' north-seeking '] magnetic pole, so
that the direction of its motion shall coincide with
the curved line proceeding from below upwards ; or if
134 MICHAEL FARADAY.
its motion parallel to itself be in a line tangential to
the curved line, but in the creneral direction of the
' CI
arrows ; or if it pass the pole in other directions, but
so as to cut the magnetic curves* in the same general
direction, or on the same side as they would be cut by
the Avire if moving along the dotted curved line ;
then the current of electricity in the wire is from r to
x. If it be carried in the reverse direction, the electric
current will be from n to p. Or if the wire be in the
vertical position, tigured p' n', and it be carried in
similar directions, coinciding with the dotted horizontal
curve so far as to cut the magnetic curves on the
same side with it, the current will be from p' to xV
When resuminof the research in i>ecember, Fara-
day investigated the point whether it was essential or
not that the rnovino- wire should, in '' cuttincj- " the
magnetic curves, pass into positions of greater or
lesser magnetic force ; or whether, always intersecting
curves of equal magnetic intensity, the mere motion
sufficed for the production of the current. He found
the latter to be true. This notion of cutting the
invisible magnetic lines as the essential act necessary
and sufficient for induction was entirely original with
Faraday. For long it proved a stumbling-block to
the abstract mathematicians, since there was, in most
cases, no direct or easy way in which to express the
number of magnetic lines that were cut. Neither
had any convention been adopted up to that time as
" [Orig-inal footnote by Fai-aday.] By mag-iietic curves, I mean
the lines of magnetic force, however modi6ed by the juxtaposition of
poles, -which would be depicted by iron filings; or those to which a
very small magnetic needle would form a tangent.
CUTTING THE MAGNETIC LINES, 185
to how to reckon numerically the number of magnetic
lines in any given space near a magnet. Later, in
1<S51, Faraday himself gave greater precision to these
ideas. He found that the current was proportional
to the velocity, Avhen the conductor Avas moving in a
uniform magnetic field Avith a uniform motion. Also,
that the quantity of electricity thrown by induction
into the circuit was directly proportional to the
"amount of curves intersected." The following
passage, from Clerk Maxwell's article on Faraday
in the " Encyclopaedia Britannica/' admirably sums
up the matter : —
The magnitude and originality of Faraday's achievement
may be estimated by tracing the subsequent history of his
discovery. As might be expected, it was at once made the
subject of investigation by the whole scientific world, but some
of the most experienced physicists were unable to avoid
mistakes in stating, in what they conceived to be more scientific
language than Faraday's, the phenomena before them. Up to
the present time the mathematicians who have rejected Fara-
day's method of stating his law as unworthy of the precision of
their science, have never succeeded in devising any essentially
different formula which shall fully express the phenomena
without introducing hypotheses about the mutual action of
things which have no physical existence, such as elements of
currents which flow out of nothing, then along a wire, and
finally sink into nothing again.
After nearly half a century of labour of this kind, we may
say that, though the practical applications of Faraday's dis-
covery have increased and are increasing in number and value
every year, no exception to the statement of these laws as
given by Faraday has been discovered, no new law has been
added to them, and Faraday's original statement remains to
this day the only one which asserts no more than can be
verified by experiment, and the only one by wliicli the theory
186 MICHAEL FAEADAY.
of the phenomena can be expressed in a manner which is
exactly and nnmerically accurate, and at the same time within
the range of elementarj^ methods of exposition.
In the 3'Gar 1831, Avhicli witnessed this master-
piece of scientitic research, Faraday was busy in
man}' other ways. He was still undertaking chemical
anal3'ses and expert work for fees, as witness his
letter to Phillips on p. 62. He w\as also, until
November, on the Council of the Royal Society. To
the " Philosophical Transactions " he contributed a
paper " On Vibrating Surfaces," in wdiich lie solved a
problem in acoustics which had previously gone with-
out explanation. It had long been know^n that in the
experiments of obtaining the patterns called "Chladni's
figures," by strewing powders upon vibrating plates,
wdiile the heavier powders, such as sand, moved into
the nodal lines, lighter substances, such as lycopodium
dust, collected in little circular heaps over the parts
Avhere the vibration w^as most energetic. Faraday's
explanation was that these lighter powders were
caught and whirled about in little vortices wdiich
formed themselves at spots wdiere the motions "were
of greatest amplitude.
He also wrote a paper " On a Peculiar Class of
Optical Deceptions," dealing with the illusions that
result from the eye being shown in successive glimpses,
as between the teeth of a revolving wheel, different
views of a moving body. This research Avas, in eflect,
the starting point of a whole line of optical toys, begin-
ning Avith the phenakistiscope or stroboscope, wdiich
developed through the zoetrope andpraxino-scope into
the Idiiematograph and animatograph of recent date.
LECTURES ON PHYSICAL SUBJECTS. 187
He gave four afternoon lectures at the Royal
Institution and live Friday evening discourses. These
were on optical deceptions, on light and phosphor-
escence, being an account of experiments recently
made by Mr. Pearsall, chemical assistant in the Insti-
tution ; on oxalamide, then recently discovered by M.
Dumas ; on Trevelyan's experiments about the produc-
tion of sound by heated bodies ; and on the arrange-
ments assumed by particles upon vibrating surfaces.
In 1832 he gave five Friday evening discourses,
four of which related to his own researches. In
August he entered upon the third series of " Experi-
mental Researches in Electricity," which was devoted
to the identity of electricities derived from different
sources, and on the relation by measure of common
[i.e. frictional] and voltaic electricity. He did not
like any doubt to hang about as to whether the
electricity obtained from magnets by induction was
really the same as that obtainable from other sources.
Possibly he had in his mind the difficulties which had
arisen thirty years before over the discoveries of
Galvani and Volta, when it was so far doubted whether
the electricity in currents from piles and batteries of
cells was the same as the electricity evoked by
friction, that the distinctive and misleading name of
" galvanism " was assigned to the former. He com-
mented on the circumstance that many philosophers
— and he included Davy by name in an explicit
reference — were vainly drawing distinctions "^ between
"' The entire uselessnesa as well as the misleading effects of yiicli
unscientific nomenclature might well be taken to heart by those
electrophysiologists and electrotherapeutiats who still indulge in the
jargon of " franklinisation," " faradisation," and '' galvanisation."
138 MICHAEL FARADAY.
electricities from diflerent sources, or at least doubt-
ing whether their identity "were proven. His first
point "was to consider whether " common electricity,"
" aninjal electricity," and " magneto-electric currents "
could, like "voltaic electricit3^" produce chemical
decompositions. He began by demonstrating that an
ordinar}^ electric discharge from a friction machine
can affect a suitably disposed galvanometer. One of
his instruments of sufficient sensitiveness was sur-
rounded by an enclosing cage of double metal foil and
wire-work, duly connected to " earth," so as to render
it independent of all disturbances by external electric
charges in its neighbourhood. His '* earth " for this
purpose consisted of a stout metal wire connected
through the pipes in the house to the metallic gas-
pipes belonging to the ^^i-^blic gas works of London,
and also with the metallic water-pipes of London — an
effectual " discharging train." He used a friction
electric machine Avith a glass plate 50 inches in
diameter, and a Leyden-jar battery of fifteen jars, each
having about 84 square inches of coated glass. This
battery of jars was first charged from the n^achine
and then discharcred throusfh a wet thread four feet
long, and through the galvanometer to earth via the
" discharging train." Having by this means satisfied
himself that these electric discharges could deflect a
galvanometer, whether through the wet thread, a
copper wire, or through water, or rarefied air, or by
connection through points in air, he went on to the
question of chemical decomposition. Dipping two
silver wires into a drop of solution of sulphate of
copper, he found that one of them became copper-
IDENTITY OF ELECTRICITIES. 139
plated by the electricity that was evolved by 100 or
200 turns of the disc machine. He bleached indigo,
turned starch purple with iodine liberated from iodide
of potassium, exactly as might have been done by a
" volta-electric current " from a battery of cells. He
also decomposed water, giving due recognition to the
antecedent experiments of Van Troostwyk, Pearson,
and Wollaston.
In the paper which he drew up he compares
these results Avith others made with electric dis-
charges from an electric kite and with those of the
torpedo and other electric fishes. He recapitulates
the properties of magneto-electricity and the proofs
now accumulating that it can decompose water. He
drew up a schedule of the different effects which
electricity can produce, and of the different sources of
electricity, showing in tabular form how far each so-
called kind of electricity had been found to produce
each etf'ect. The conclusion was that there is no
philosophical difference between the different cases ;
since the phenomena produced by the different kinds
of electricity differ not in their character but only in
degree. " Electricity, ivhatever may he its source, is
identical in its nature." On comparing the effects
produced by different discharges, he concludes that
"if the same absolute quantity^ of electricity pass
through the galvanometer, whatever may be its
intensity, the deflecting force upon the magnetic
needle is the same." He was then able to go on to a
^' In modern lunyuag-e this would be called the time-iutegTal of the
discharge. The statement is sti-ietly true if the L,^ilvanometer (as was
the case "with Faraday's) is one of relatively long- period of oscillation.
140 MICHAEL FARADAY.
quantitative comparison bet^veen the ^' quantity " of
electricity Irom different sources, and came to the
conckision that both in magnetic deflection and in
chemical force the current of electricity given by his
standard battery for eight beats of his watch was
equal to that of the friction machine evolved by thirty
revolutions ; further, that " the chemical power, like
the magnetic force, is in direct proportion to the
absolute quantity of electricity which passes."
This series of researches was published in January,
1833. In April of the same year he sent to the
Royal Society another paper — the fourth series — on
electric conduction. It arose from the surprising
observation that, though water conducts, ice acts as
a complete non-conductor. This led to an examin-
ation of the conducting power of fusible solids
in general. He found that as a rule — excepting
on the one hand the metals, which conduct whether
solid or liquid, and on the other hand fatty bodies,
which are ahvays non-conductors — they assume con-
ducting power when liquefied, and lose it when
congealed. Chloride of lead, of silver, of potassium,
and of sodium, and many chlorates, nitrates, sul-
phates, and many other salts and fusible substances
were found to follow this rule. All the substances
so found to act were compound bodies, and capable
of decomposition by the current. AVhen conduction
ceased, decomposition ceased also. An apparent
exception was found in sulphide of silver, which,
when heated, acquired conducting powers even before
it assumed the liquid state, yet decomposed in the
solid state. This led him on to study electro-chemical
ELECTRO-CHEMICAL WORK. 141
decompositions more closely. Here ho was following
directly in the footsteps of his master Davy, whose
discovery of the decomposition of potash and soda
by the electric current had been one of the most
prominent scientific advances resulting from the
invention of the voltaic cell. The fifth series of
researches, published in June, 1833, embodies the
work. He first combats the prevailing opinion that
the presence of water is necessary for electro-chemical
decomposition ; then analyses the views of various
philosophers — Grotthuss, Davy, De la Rive, and
others — who had discussed the question whether the
decompositions are due to attractions exercised by
the two jDoles of the electric circuit. This he contests
in the most direct manner. Already he has reason
to believe that for a given quantity of electricity
passed through the liquid the amount of electro-
chemical action is a constant quantity, and de-
pends in no way on the distance of the particles
of the decomposable substance from the poles.
He regards the elements as progressing in two
streams in opposite directions parallel to the
current, while the poles " are merely the surfaces
or doors by which the electricity enters into or
passes out of the substance suffering decomposi-
tion."
Amongst the laboratory notes of this time are
many which were never published in the '' Ex-
perimental Researches," or of which only brief
abstracts appeared. Some of these are of great
interest.
Here is one literally transcribed : —
142 MICHAEL FARADAY.
2G Feb. 1833.
Chloride J]L■(</llesiu))l.~^Yhe\l solid and wire fuzed in non-
<'onductor — When fuzed conducted vei'y "well and was
decomposed A and P Pole much action and gas -chlorine ^
At N Pole ^lagnesiuni separated and no gas. Sometimes
Magnesium burnt flying otf in globules burning brilliantly.
When wire at that pole put in Avater or white M A
[muriatic acid] matter round it acted powerfully evolving
hydrogen and forming Magnesia ; and when wire and
surrounding matter heated in spirit lamp Magnesium burnt
with intense light into Mnrinei<ia. VERY GOOD EXPT.
This recalls the " capital experiment " entry which
Sir Humphry Davy w^rote after the account of his
decomposition of caustic potash. On the 7th of
April we come to a marvellous page of speculations.
He has seen that liquids, both solutions and fused
salts, can be decomposed by the current, and that
at least one solid is capable of electrolysis. But he
finds that alloys and metals are not decomposed.
He finds that electrolysis is easiest for those com-
pounds that consist of the most diverse elements,
and is led on to speculate as to the possible con-
stitution of those conductors that the current does
not decompose. This may involve a i-ecasting of
accepted ideas ; but from such a step he does not
shrink, as the following extracts show : —
Metals meuj not be compounds of elements most fre-
quently combined, but rather of such as are so similar to
each other as to pass out of the limit of voltaic de-
composition.
13th April (same page).
If voltaic decomposition of the kind I believe then
review all substances upon the new view to see if they
may not be decomposable, tfec. itc. Ac.
ATTRACTION BY POLES DOUBTED. 143
He has now found that the facts observed do
not admit of being exphiined on the supposition
that the motion of the ions is due to the attraction
of the poles, and accordingly there follows the
entry : —
(Ap. 13, 1H33.)
A single element is never attracted by a i)ole, i.e.
Avithout attraction of other element at other pole. Hence
doubt Mr. Brande'a Exi)ts on attraction of gases and
vapours. Doubt attraction by poles altogether.
To this subject he returned in 1834 ; an inter-
vening memoir — the sixth — being taken up with
the power of metals and solids to bring about the
combination of gaseous bodies. In the seventh
series, published in January, 1834, his first work
is to explain the new terms which he has adopted,
on the advice of Whewell, to express the facts.
The so-called poles, being in his view merely doors
or ways by which the current passes, he now terms
electrodes, distinguishing the entrance and exit re-
spectively as anode and cathode,'^ while the decom-
posable liquid is termed an electrolyte, and the
decomposing process electrolysis. " Finally," he says,
in a passage (here italicised) worthy to be engTaved
in gold for the essential truth it enunciates on a
question of terminology, " I require a term to express
those bodies which can pass to the electrodes, or,
* From d^w upwards and 656s a way ; and Kara doivnivards
and 6h6s a way. The words cathode and cation are now more
usually spelled kathode and kation. Faraday sometimes spelled
the word cathion {Exp. Res. Art. 1351), as did also Whewell
(Hist, of Ind. Sciences, vol. iii. p. 166).
144 MICHAEL FAKADAY.
as they are usually called, the poles. Substances
are frequently spoken of as being" electronegative,
or elect ropofiitive, according" as they go under the
supposed influence of a direct attraction to the
positive or negative pole. But these terms are much
too significant for the use to which I should have
to put them ; for thouglt the meanings are 2:)er]iafs
r ight, they are o nhj h ypoth et ieal, a ad may he
wrong ; and then, tJtroiigh a very invperceptible but
still very dangerous, because continued, influence,
they do great injury to science, by contracting and
liniiting the Jiabitual vieivs of those engaged in
pwrsuing it. I propose to distinguish such bodies
by calling those anions which go to the anode of
the decomposing body ; and those passing to the
ccdhode, cations ; and when I shall have occasion
to speak of these together, I shall call them ions."^
Thus, the chloride of lead is an electrolyte, and
when electrolysed- evolves the two ions, chlorine
and lead, the former being an anion and the latter
a cation:' In Faraday's own bound volume of the
" Experimental Researches " he has illustrated these
terms by the sketch here reproduced. (Fig. 12.)
Faraday's letter to Whewell when he consulted
him as to the new words has not been preserved. He
discarded, when the paper was printed, the terms he
had first used. Whewell's replies of April 25th and
May 5 th, 1834, have been preserved and are printed
in Todhunter's biography of Whewell. From the later
of the two the following passage is extracted : —
*" Litrrally, t/ie travellers, the things "which are going-.
NEW NOMENCLATUKE.
145
[Wheivell to F<trad<n/], May 5, 18:34.
Tf you take anode and cathode^ I would pro])Ose for the tAvo
elements resulting from electrolysis the terms anion and cation,
which are neuter participles signifying that tvhich goes up, and
that which goes doivn ; and for the two together you might
use the term ions. . . . The word is not a substantive in
Greek, but it may easily be so taken, and I am persuaded that
the brevity and simplicity of the terms you will thus have will
in a fortnight procure their universal acceptation. The cuiion
is that Avhicli goes to the anode, the cation is that Avhich goes
t»J^7/y^^
Yir._ l-I.
to the cathode. The th in the latter word arises from the
aspirate in hodos (way), and therefore is not to be introduced
in cases wdiere the second term has not an aspirate, as io7i
has not.
On May 15th Faraday replied as follows: —
[Faraday to WhewelL]
I have taken your advice and the names, and use anode,
cathode, anions^ cations and io7is ; the last I shall have but
little occasion for. I had some hot objections made to thi-ni
here, and found myself very much in the conditittn of the man
with his Son and Ass, who tried to please everybody- but
when 1 held up the shield of your authority it was wonderful
to observe how the tone of objection melted away. I am quite
K
146 MICHAEL FARADAY.
delighted with the facility of expression which the new terms
give me, and shall ever be your debtor for the kind assistance
you have given nie,
As though to prepare the way for a still further
cutting of himself adril't from the slavery of using
terms that might be found misleading, he added the
followino^ note : —
It will be well understood that I am giving no opinion
respecting the nature of the electric current now, beyond what
I have done on former occasions ; and that though I speak of
the current as proceeding from the pares which are positive to
those which are negative, it is merely in accordance with the
conventional, though in some degree tacit, agreement entered
into by scientific men, that they may have a constant, certain,
and definite means of referring to the direction of the forces of
that current.
The "former occasions" is a reference to an earlier
suggestion that a current might mean anything pro-
gressive, whether a flow in one direction or two fluids
moving in opposite directions, or merely vibrations, or,
still more generally, progressive forces. He had
expressly said that what we call the electric current
'' may perhaps best be conceived of as an axis of 'poivcr
having contrary forces, cvactly equal in amount, in
contrary directions."
He then suggests as a measurer of current the
standard form of electrolytic cell ever since known as
the voltameter. He preferred that kind in Avhich
Avater is decomposed, the quantity of electricity which
had flowed through it being measured by the quantity
of the gas or gases evolved during the operation.
Before adopting this he undertook careful experiments
iD
ELECTRO-CHEMICAL LAWS. 147
in which his fine manipulative skill, no less than his
chemical experience, Avas called into service to veriiy
the fact that the quantity of water decomposed was
really proportionate to the quantity of electricity
which has been passed through the instrument.
Having this standard, he investigated numerous other
cases of decomposition by the current, and so arrived
at a substantial basis for the doctrine of definite
electro -cheriiical action. Speaking of the substances
into which electrolytes are divided by the current,
and which he had called ions, he says : " They are
combining bodies ; are directly associated with the
fundamental parts of the doctrine of chemical affinity ;
and have each a definite proportion, in which they
are always evolved during electrolytic action. . . .
I have proposed to call the numbers representing the
proportions in which they are evolved electro -cheniical
eqiiivalents. Thus hydrogen, oxygen, chlorine, iodine,
lead, tin are ions ; the three former are anions, the
two metals cations, and 1, 8, 36, 125, 104, 58, are their
electro-chemical equivalents nearly."
This fundamental law being set upon an iinpreg-
nable basis of facts, he goes on to speculate upon the
absolute qtutntity of electricity or electric power
belonging to different bodies ; a notion Avhich only
within the last few years has found general acceptance.
In developing this theory he uses the following
language : —
According to it [i.e. this theory], the equivalent weighty of
bodies are simply those quantities of them Avhich contain
equal quantities of electricity, or have naturally equal elec-
tric powers ; it being the electricity which determines the
148 MICHAEL FAKADAY.
eiiuivalent number, hrrausr it determines the combining force.
Or, if we adopt the atomic theory or phraseology, then the
atoms of bodies Avhich are equivalents to each other in their
ordinary chemical action, have equal quantities of electricity
naturally associated with thtm. But I must confess I am
jealous of the term atom. . . .
Here we find the raoderu doctrine of electrons or
unitary atomic charges, clearly formulated in 1834.
In the course of this speculation he remarks that " if
the electrical power which holds the elements of a
g'rain of water in combination, or which makes a gi'ain
of oxygen or hydrogen in the right proportions unite
into water when they are made to combine, could be
thrown into the condition of a current, it would exactly
equal the current required for the separation of that
grain of water into its elements again." And all this
years before there was any doctrme of the conservation
of energy to guide the mind of the philosopher ! The
passage just cited contains the germs of the thermu-
dynamic theory of electromotive forces worked out
a dozen years later by Sir William Thomson (now
Lord Kelvin), by which theory we can predict the
electromotive forces of any given cliemical com-
bination from a knowledge of the heat evolved b}^
a given mass of the product in the act of combinmg.
The eii^hth series of the researches, which was
read in June, 1834, deals chiefly Avith voltaic cells and
batteries of cells. He is now applying to the opera-
tions inside the primary cell the electrochemical
principles learned by the study of electrolysis in
secondary cells. His thoughts have been incessantly
playing around the problem of electrolytic conduction.
ANOTHER UNSUCCESSFUL QUEST. 149
He was convinced that the forces which shear the
anions from conihination with the cations and transfer
them in opposite directions must be inherent Ijcforc
the circuit is completed, and therefore before any
actual transfer or movement takes place. ''It seems to
me impossible," he says, " to resist the idea that it [the
''transfer," or "what is called the voltaic current"]
must be preceded by a state of tension in the fluid.
I have sought carefully for indications of a state
of tension in the electrolytic conductor ; and conceiv-
ing that it might produce something like structure,
either before or durint^ its discharf:^e, I endeavoured
to make this evident by polarised light." He used
a solution of sulphate of soda, but without the
slightest trace of optical action in any direction of
the ray. He repeated the experiment, using a solid
electrolyte, borate of lead, in its non-conducting state,
but equally without result.
During the time of these electrochemical researches
in 1S33 and 1834, Faraday's activities for the Royal
Institution were undiminished. In 1833 he gave
seven Friday discourses, three of them on the re-
searches in hand, one on Wheatstone'^ investio'ation
of the velocity of the electric spark, and one on the
practical prevention of dry rot in timber, which was
afterwards republished as a pamphlet, and ran to two
editions. In 1834 he gave four Friday discourses ;
two on his electrochemical researches, one on Ericsson's
heat-engine, and the other on caoutchouc.
The ninth series of electrical researches occupied
the autumn of 1834. In it he returns to the study
of the mametic and inductive actions of the current,
150 MICHAEL FARADAY.
investigating the self-induced spark at the break of
the circuit, to ^\-hich his attention had been dh'ccted
by Mr. W. Jenkin. Several points in this research
are little known even now to electricians, the labora-
tory notes being much more detailed than the pub-
lished paper. He describes an exceedingly neat high-
speed break for producing rapid interruptions, using
for that purpose stationary ripples on the surface of
a pool of mercury. In a wonderful day's work on
loth November, tilling thirty-four pages of the labora-
tory book, illustrated with numerous unpublished
sketches, he tracks out the properties of self-in-
duction. He proves that the spark {on breaking
circuit) from a Avire coiled up in a helix is far
brighter than that from an identical wire laid out
straight. He tinds that a non-inductive and, there-
fn'e. sp^arkless coil can be made bv winding the
wire in two opposite helices. "Thus the Avhole [in-
ductive] etfect of the length of wire was neutralised
by the reciprocal and contrary action of the two
halves which constituted the helices in contrary
directions." The next da}- he writes : ■• These effects
show that every part of an electric circuit is acting
by induction on the neighbouring parts of the same
current, even in the ><aine wire and the same part
cif the wire."
On 22nd November he is trying another set of
experiments, also never fully pubhshed. They relate
to the diminution of self-induction of a straight
conductor by dividing it into several parallel strands
at a small distance apart from one another. The
note in the laboratory book runs thus : —
EFFECTS OF SELF-IXDrCTIOX.
151
Coj^pcr wire .r^^ of iiiLli in diameter. Six lengths of five
feet each, soldered at ends to piece of oojiper plate so as
form terminations, and tho>e amalgamated. When this
bundle was used to eonnert the electro-motor it gave but
very feeble spark on breaking contact, but the spark was
sensibly better when the wires are held together so as to
act laterally than when they were opened out from each
other, thus showing lateral aetion.
Made a larger bundle of the same fine copper wire.
There were -i' lengths oi IS feet -2 inches each and the
thick terminal pieces oi copper wire 6 inches long and ,' of
inch thick.
This bundle he ooinpared with a length oi 19 feet
^^ inches of a single copper wire ^ inch in diameter.
having about equal sectional area. The latter gave
decidedly the largest sparks on breaking circuit.
Faraday did not see tit at this time to accept
the idea, suggested indeed by himself in 1S31. that
these effects of self-induction were the analogue of
momentum or inertiii. That explanation he set aside
on finding that the same wire when coiled had
greater self-inductive action than Avhen straight.
Had lie at that time grasped this analogy, he would
have seen that the very property which gives rise
to the spark at break of circuit also retards the
raptid growth of a current : and then the experiment
described above would have shown hiiu that Sir
W. Snow Harris was right in preferring flat copper
ribbon to a round wire of equivalent section as a
152 MICHAEL FARADAY.
material for lightning conductors. He was, however,
disappointed to find so small a ditibrence between
round wires and parallel strands. The memoir as
published contains an exceedingl}^ interesting con-
clusion : —
Notwithstanding that the effects appear only at the
making and breakini;' of contact (the current, reniaininjj:
unaffected, seemingly, in the interval,) I cannot resist the
impression that there is some connected and correspondent
effect 1 iroduced by this lateral action of the elements of
the electric stream during the time of its continuance. An
action of this kind, in fact, is evident in the magnetic
relations of the parts of tlie current. Hut admitting (as
we may do for the moment) the magnetic forces to constitute
the jtower which in'oduces such striking and different results
at the commenceuient and termination of a current, still
there appears to be a link in the chain of effects — a wheel
in the physical mechanism of the action, as yet unrecognised.
The tenth scries of researches, on the voltaic
battery, though completed in October, 1S84, was not
published till June, 1S35.
The next research, begun in the autumn of 1835.
after a lull of about eii>'ht months, lasted over two
years. It was not completed till December, 1837. This
investigation took Faraday away from magnetic and
electrochemical matters to the old subject of statical
electric charges, a subject hitherto untouched in his
researches. But he had long brooded over the
question as to the nature of an electric charge. Over
and over again, as he had Avatched the inductive
eftcct of electric currents acting from wire to wire,
his mind turned to the old problem of the inductive
intluenco — discovered eighty years before, by John
ACTIOX IN A MEDIUM. l-^*^
Canton — exerted, apparently at a distance, by clecti-ic
charo'es. He had learned to distrust action at .a
distance, and now tlie time was ripe for a searchini:^
inquiry as to whether electric ivflwvce, or induction "^"
as it was tlien called, was also an action propagated
by contiguous actions in the intervening medium.
Faraday had rlone no special electric work during
the first nine months of 1835. He had worked at
a chemical investigation of fluorine through the
spring, and in July took a hurried tour in Switzer-
land, and returned to work at fluorine. Not till
November 3rd does he turn to the subject over which
he had been brooding. On that date, intercalated
between notes of his chemical studies, filling a dozen
pages of the laboratory book, are a magnificent series
of speculations as to the nature of charges, and on
the part played by the electric — or, as we should now
say, the dielectric — medium. They begin thus: —
" Have been thinking much lately of the relation
of common and voltaic electricity, of induction by the
former and decomposition by the latter, and am quite
convinced that there must be the closest connection.
Will be first needful to make out the true character " —
note the phrase^" of ordinary electrical phenomena."
'■ The term iinlHrflon appears to have heon originally used, in
contradistinction to contact or coi/niict'uii, to connote those effects
which apparently are in the class of actions at a distance. Thus
we may have induction of a charge by a charge, or of a mngnct-
pole by a magnet-polo. To these Faraday had added the induction
of a current by a current^ and the induction of a current by a
moving magnet. Amid such varyinf^- adaptations of the word in-
dia'tion, there is much gain in allotting to the electrostatic induction
of charges by charges the distinguishing name of 'influeiwe., as
suggested by Priestley.
154 MICHAEL FARADAY.
The following notes are for experiment and ob-
servation.
" Does common electricity reside upon the sur-
face of a conductor or upon the surface of the
[di-]electric in contact with it ? "
He ^oes on to consider the state of a dielectric
substance, such as s^lass, when situated between a
positively charged and a negatively charged surface,
as in a charged Ley den jar, and argues from analogy
thus : —
" Hence the state of the plate [of glass] under
induction is the same as the state of a magnet, and if
split or broken would present new P[ositive] and
N[egative] surfaces before not at all evident." This
speculation was later verified by Matteucci.
" Probable that phenomena of induction prove
more decidedly than anything else that the electricity
is in the [di-]electric not in the conductor."
He still worked for a .week or two on fluorine,
interposing some experiments on the temperature-
limit of magnetisation, but on December 4th decides
not to go on with fluorine at present. Then, beginning
on December 5th, there follow twenty-nine pages of
the laboratory diar^^, illustrated with sketches. He
had borrowed from a Mr. Kipp a large deep copper
pan thirty-five inches in diameter, and he set to work
electrifying it and exploring the distribution of the
charges, inside and out, and the inductive effect on
objects placed within. Everywhere he is mentally
comparing the distribution of the effects with that of
the flow of currents in an electrolyte. Before many
days he writes : —
PREGNANT SUGGESTIONS. 155
"It appears to me at present that ordinar/j and
ch'ctrolijfic induction are identical in their first nature,
but that the latter is followed by an effect which
cannot but from the nature and state of the substances
take" place with the former." Then conies this preg-
nant suggestion : —
" Try induction through a sohd crystalline body as
to the consequent action on polarized light."
By the end of a Aveek he had begun to suspect
that his magnet analogy went farther than he was at
first prepared to hold. The action of a magnet was
along curved lines of force. So he asks : —
" Can induction through air take place in curves
or round a corner — can probably be found experi-
mentally — if so not a radiating effect."
After ten days more he has made another step.
" Electricity appears to exist only in 'polarity as in
air, glass, electrolytes, etc. Now metals, being con-
ductors, cannot take up that poLar state of their own
power, or rather retain it, and hence probably cannot
retain developed electric forces.
" Metals, however, probably hold it for a moment, as
other things do for a longer time; an end coming at
last to ah."
This, it will be observed, is nothint^ more or
less than Clerk Maxwell's theory of conduction as
beins^ the breakino^ down of an electrostatic strain.
In January, 1836, followed the famous experiment
of building a twelve-foot cube, which when electrified
exteriorly to the utmost extent, showed inside no trace
of electric forces. The account in the unpublished
156 MICHAEL FARADAY.
MS. of the lal)oratory book is, as is the case with
so many of these middle-period researches, much
fuller than the published re'--^urae of them in the
" Experimental Researches." All throu^-h 1S3(J he
was still at work. Even Avheli on a holida}' in the
Isle of "Wio'ht, in Aus^ust, he t<^ok his notebook with
him, and writes : —
" After much consideration (here at Ryde) of the
manner m which the electric forces are arranged in
the various phenomena generally, I have come to
certain conchisions Avhich I will endeavour to note
down without connnitting m3'self to any opinion as to
the cause of electricity, i.e. as to the nature of the
poAver. If electricity exist independently of matter,
then I think that the hypothesis of one fluid Avill not
stand asfainst that of two fluids. There are, I think,
evidently, what I may call two elements of power of
equal force and acting towards each other. These
may conventionally be represented by oxygen and
hydrogen, which represent them in the voltaic battery.
But these powers ma}- be distinguished only hi/ du'cc-
tion, and may be no n:iore separate than the north
and south forces in the elements of a mametic needle.
They may be the polar points of the forces originally
placed in the particles of matter : and the description
of the current as an axis of poAver which I have
formerly driven suo-o-ests some similar o-eneral im-
pression for the forces of quiescent electricity. Law
of electric tension might do, and though I shall use
the terms positive and negative, by them I merel}^
mean the termini of such lines."
Rio-ht on until November 30th, 1837, this research
ACTION AT A DISTANCE UNTHINKABLE. 157
was continued. The sminnary of this and the succeed-
ing researches of 1^38 on the same subject, drawn up
by Professor Tyndall,^ is at once so masterly and so
impartial that it cannot be bettered. It is therefore
here transcribed without alteration.
His first great paper on frictiunal electricity was sent to the
Royal iSociety on November 30, 1837. We here tiad him face
to face with an idea which beset liis mind throughout his whole
subseijuent life— the idea of <iction <tf n distance. It perplexed
and bewildered him. In his attempts to ,L;et rid of this per-
plexity he was often nnconsciously rebelling against the limit-
ations of the intellect itself. He loved to (p.iote Newton upon
this point : over and over again he intntduces his memorable
words, "That gravity should be innate, inherent, and essential
to matter, so that one body may act ui)on another at a distance
through a vacuum and without the mediation of anything else,
by and through which this action and force may be conveyed
from one to another, is to me so great an absurdity, that I
believe no man who has in philosophical matters a competent
faculty of thinking can ever fall into it. Gravity must be
caused by an agent acting constantly according to certain laws;
but whether this agent be material or immaterial I have left to
the consideration of my readers." f
Faraday does not see the same ditticulty in his contiguous
particles. And yet by transferring the conception from masses
to particles we simply lessen size and distance, but Ave do not
alter the quality of the conception. Whatever ditticulty the
mind experiences in conceiving of action at sensible distances,
besets it also when it attempts to conceive of action at insensible
distances. Still the investigation of the point whether electric
and magnetic effects were Avrought out through the intervention
of contiguous particles or not, had a physical interest altogether
ajiart from the metaphysical difficulty. Faraday grapples with
the subject experimentally. V>y simple intuition he sees th^t
* " Faraday as a Discoverer," p, 67.
t Newton's third letter to Bentley.
158 MICHAEL FARADAY.
action at a distance must be exerted in straight lines. Gravity,
he knows, will not turn a corner, but exerts its pull along a
right line ; hence his aim and efibrt to ascertain whether
electric action ever takes place in curved lines. This once
proved, it would follow that the action is airried on by vieans
of a medium surrounding the electrified bodies. His experi-
ments in 1837 reduced, in his opinion, this point to demonstra-
tion. He then found that he could electrify by induction an
insulated sphere placed completely in the shadow of a body
which screened it from direct action. He pictured the lines of
electric force bending round the edges of the screen, and re-
uniting on the other side of it ; and he proved that in many
cases the augmentation of the distance between his insulated
sphere and the inducing body, instead of lessening, increased
the charge of the sphere. This he ascribed to the coalescence
of the lines of electric force at some distance behind the screen.
Faraday's theoretic views on this subject have not received
general acceptance, but they drove him to experiment, and
experiment with him was always prolific of results. By suit-
able arrangements he places a metallic sphere in the middle of
a large hollow^ sphere, leaving a space of something more than
half an inch between them. The interior sphere was insulated,
the external one uninsulated. To the former he communicated
a de6nite charge of electricity. It acted by induction upon
the concave surface of the latter, and he examined how this act
of induction was affected by placing insulators of various kinds
between the two spheres. He tried gases, liquids, and solids,
but the solids alone gave him positive results. He constructed
two instruments of the foregoing description, equal in size and
similar in form. The interior sphere of each communicated
with the external air by a brass stem ending in a knob. The
apparatus was virtually a Leyden jar, the two coatings of Avhich
were the two spheres, with a thick and variable insulator
between them. The amount of charge in each jar was deter-
mined by bringing a proof-plane into contact with its knob,
and measuring by a torsion balance the charge taken away.
He first charged one of his instruments, and then dividing the
charge with the other, found that when air intervened in both
SPECIFIC INDUCTIVE CAPACITY.
159
cases, the charge was equally divided. But when shell-lac,
sulphur, or spermaceti was interposed between the two spheres
of one jar, while air occupied this interval in the other, then he
found that the instrument occupied by the "solid dielectric"
took more than half the original charge. A portion of the
charge was absorbed in the dielectric itself. The electricity
took time to penetrate the dielectric. Immediately after the
Fig. It.
discharge of the apparatus no trace of electricity was found
upon its knob. But aftei a time electricity was found there,
the charge having gradually returned from the dielectric in
which it had been lodged. Different insulators possess this
power of permitting the charge to enter them in difierent
degrees. Faraday tigured their particles as polarised, and he
concluded that the force of induction is propagated from
particle to particle of the dielectric from the inner sphere to
the outer one. This power of propagation possessed by in-
sulators he calls their " Hpecific Inductive Capacity T
Faraday visualises with the utmost clearness the state of
his contiguous particles ; one after another they become
160 MICHAEL FARADAY.
charged, each succeeding particle dependiiii;" for its charge
upon its predece.-ssor. And now he seeks to break do^\^i the
Avail of partition between conductors and insulators. " Can
Ave not," he says, "by a gradual chain of association carry up
discharge from its occurrence in air through spermaceti and
water to solutions, and then on to chloricies, oxides, and metals,
without any essential change in its character?" Even copper,
he urges, offers a resLstance to the transmission of electricity.
The action of its particles ditfers from those of an insulator
only in degree. They are charged like the particles of the
insulator, but they discbarge Avith greater ease and rapidity ;
and this rapidity of molecular discharge is Avhat Ave call
conduction. Conduction, then, is ahvays preceded by atomic
induction ; and Avhen through some quality of the body, Avhich
Faraday does not define, the atomic discharge is rendered sIoav
and difficult, conduction passes into insulation.
Though they are often obscure, a fine vein of philosophic
thought runs through these investigations. The mind of the
philosopher dwells amid those agencies which underlie the
visible phenomena of induction and conduction ; and he tries
by the strong light of his imagination to see the very molecules
of his dielectrics. It Avould, hoAvever, be easy to criticise these
researches, easy to shoAv the looseness, and sometimes the
inaccuracy, of the phraseology emjiloyed ; but this critical
spirit Avill get little good out of Faraday. Rather let those
Avho ponder his Avorks seek to realise the object he set before
him, not permitting his occasional vagueness to interfere with
their appreciation of his speculations. We may see the ripples,
and eddies, and vortices of a flowing stream, AA^thout being
able to resolve all these motions into their constituent elements ;
and so it sometimes strikes me that Faraday clearly saAv the
play of fluids and ethers and atoms, thougli his previous train-
ing did not enable him t(t rt^solve what he saAv into its con-
stituents, or descritie it in a manner satisfactory to a mind
versed in mechanics. And then again occur, I confess, dark
sayings, difficult to be understood, Avhich disturb my confidence
in this conclusion. It must, however, ahvays be remembered
that he works at the very boundaries of our knoAvledge, and
CABLE RETAltDATJOX PREIUCTED. 161
that his mind habitually dwells in the '' boundless contiguity
of shade " by which that knowledge is surrounded.
In the researches now under review the ratio of speculation
and reasoning to experiment is far higher than in any of
Faraday's previous A^orks. Amid much that is entangled and
dark we have flashes of wondrous insight and utterances
which seem less the product of reasoning than of revelation.
I will confine myself here to one example of tliis divining
power : — By his most ingenious device of a rapidly rotating
mirror, Wlieatstone had proved that electricity recjuired time
to pass through a wire, the current reaching the middle of the
wire later than its two ends. "If," says Faraday, "the two
ends of the wire in Professor Wheatstone's experiments were
immediately connected with two large insulated metallic
surfaces exposed to the air, so that the primary act of induc-
tion, after making the contact for discharge, might be in part
removed from the internal portion of the wire at the first
instance, and disposed for the moment on its surface jointly
with the air and surrounding conductors, then I venture to
anticipate that the middle spark would be more retarded than
before. And if those two plates were the inner and outer
coatings of a large jar or Leyden battery, then the retardation
of the spark would be much greater." This was only a
prediction^ for the experiment was not made. Sixteen years
subsequently, however, the proper conditions came into play,
and Faraday was able to show that the observations of Werner
Siemens and Latimer Clark on subterraneous and submarine
wires were illustrations, on a grand scale, of the principle
which he had enunciated in 1838. The wires and the sur-
rounding water act as a Leyden jar, and the retardation
of the current predicted by Faraday manifests itself in every
message sent by such cables.
The meaning of Faraday in these meniou's on induction
and conduction is, as I have said, by no means always
clear ; and the difficulty will be most felt by those who are
best trained in ordinary theoretic conceptions. He does not
know the reader's needs, and he therefore does not meet
them. For instance, he speaks over and over again of the
L
162 MICHAEL FARADAY.
impossibility of charging a body with one electricity, though
the impossibility is by no means evident. The key to the
ditticulty is this. He looks upon every insulated conductor
as the inner coating of a Leyden jar. An insulated sphere
in the middle of a room is to his mind such a coating ; the
Avails are the outer coating, while the air between both is
the insulator, across which the charge acts by induction.
AYithout this reaction of the -walls upon the sphere, you
conld no more, according to Faradny, charge it with electricity
than you could charge a Leyden jar, if its outer coating were
removed. Distance with him is immaterial. His strength
as a generaliser enables him to dissolve the idea of magni-
tude ; and if you abolish the walls of the room— even the
earth itself — he would make the sun and planets the outer
coating of his jar. I dare not contend that Faraday in these
memoirs made all these theoretic positions good. But a
pure vein of philosophy runs through these writings; while
his experiments and reasonings on the forms and phenomena
of electrical discharge are of imperishable importance.
In another part of the tAvelfth memoir, not in-
eluded in the above suminar}^ Farada}^ deals with
the disruptive discharge, and with the nature of the
spark under varying conditions. This is continued
on into the thirteenth memoir, read February, 1838,
and is extended to the cases of " brush " and " glow "
discharges. He discovered the existence of the very
remarkable phenomenon of the " dark " discharge
near the cathode in rarefied air. He sought to
correlate all the various forms of discharge, as show-
ing the essential natm'e of an electric current. " If
a ball be electrified positively/' he says, " in the
middle of a room, and be then moved in any
direction, effects will be produced, as if a current
in the same direction (to use the conventional mode
OOrNAGE OF NEW WORDS. 163
of expression) had existed." This is the theory of
convection currents later adopted by Maxwell, and
verified by experiment by Rowland in 1876.
In the course of this research on induction,
Faraday had, as we have seen, been compelled to
adopt neAV ideas, and therefore to adopt new names
to denote them. The term dielectric for the medium
in or across which the electric forces operate was
one of these. As in previous cases, he consulted
with his friends as to suitable terms. In this in-
stance the following letter from Wlieweh explains
itself. The letter to which it is a reply has not
been preserved, but the reference to Faraday's ob-
jection to the word current may be elucidated by
a comparison with what Faraday Avrote in criticism
of that word on pages 146 and 212.
[Rev. IF. Whewell to J/. Faraday.]
Tkin. Coll., Cambridge, Oct. 14, 1837.
My dear 8ik, — I am always glad to hear of the progress
of your researches, and never the less so because they require
the fabrication of a new word or two. Such a coinage has
always taken place at the great epochs of discovery ; like
the medals that are struck at the beginning of a new reign : —
or rather like the change of currency produced by the
accession of a new sovereign ; for their value and inllueiice
consists in their coming into common circulation. I am
not sure that I understand the view^s which you are at
present bringing into shape sufficiently well to suggest any
such terms as you think you want. I think that if I could
have a quarter of an hour's talk with you I should probably
be able to construct terras that would record your new
notions, so far as I could be made to understand them
better than I can by means of letters : for it is difficult
164 MICHAEL FARADAY.
without question and discussion to catch the precise kind
of relation which you want to express. However, by way
of beginning such a discussion, I woukl ask you whether
you want abstract terms to denote the different and related
conditions of the body which exercises and the body which
suffers induction ? For though both are active and both
passive it may still be convenient to suppose a certain
ascendancy on one side. If so would two such words as
inductricity and inducteity answer your purpose '? They
are not very monstrous in their form ; and are sufficiently
distinct. And if you w^int the corresponding adjectives
yo\i may call the one the inductric, and the other the
indncteous body. This last word is rather a startling one ;
but if such relations are to be expressed, terminations are
a good artifice, as we see in chemistry : and I have no
doubt if you give the world facts and laws which are better
expressed with than without such solecisms, they will soon
accommodate to the phrases, as they have often done to
worse ones. But I am rather in the dark as to whether
this is the kind of relation which you want to indicate.
If not, the attempt may perhaps serve to shew you where
my dulness lies. I do not see my way any better as to
the other terms, for I do not catch your objection to
current., which appears to me to be capable of jogging on
very well from cathode to anode^ or vice versa. As for
positive and negative, I do not see why cathodic and anodic
should not be used, if they will do the service you want
of them.
I expect to be in London at the end of the month,
and could probably see you for half an hour on the 1st of
November, say at 10, 11, or 12. But in the mean time I
shall be glad to hear from you whether you can make
anything of such conundrums as I have mentioned, and am
always yours very truly,
W. Whewell.
M. Faraday Esq"*
Royal Institution,
LATERAL ACTIONS OF CURRENT. 105
The concluding part of the thirteenth memoir,
in "which these new terms are used, is an exceedingly
striking speculation on the lateral or transverse
effects of the current. In caUing special attention
to them, he says : " I refer of course to the magnetic
action and its relations ; but though this is the
only recognised lateral action of the current, there
is great reason for believing that others exist and
would by their discovery re"v\^ard a close search for
them." He seems to have had an instinctive per-
ception of something that eluded his grasp. Not
until after Maxwell had given mathematical form
to Faraday's own suggestions was this vision to be
realised. He is dindy aware that there appears to
be a lateral tension or repulsion possessed by the
lines of electric inductive action ; and onward runs
his thought in free speculation : —
When current or discharge occurs between two bodies,
previously under inductrical relations to each other, the
Unes of inductive force will weaken and fade away, and,
as their lateral repulsive tension diminishes, will contract
and ultimately disap|>ear in the line of discharge. May not
this be an effect identical with the attractions of similar
currents ? i.e. may not the passage of static electricity into
current electricity, and that of the lateral tension of the
lines of the inductive force into the lateral attraction of
lines of similar discharge, have the same relation and de-
pendences, and run parallel to each other?
Series fourteen of the memoirs is on the nature
of the electric force and on the relation of the
electric and magnetic forces, and comprises an in-
conclusive inquiry as to a possible relation between
166 MTCKAKL FARADAV.
specitic inductive capacity and axes of crystallisation
in crystalline dielectrics — a relation later assumed
as true by Maxwell even before it was demonstrated
by Von Boltzmann. In this memoir, too, occurs a
description of a sin^iple but efi'ective induction balance.
Then he asks what happens to insulating substances,
such as air or sulphur, when they are put i-n a place
where the magnetic forces are varying ; they ought,
he thinks, to undergo some state or condition corre-
sponding to the state that causes currents in metals
and conductors, and, further, that state ought to
he one of tension. "I have," he says, "by rotating
non-conducting bodies near magnetic poles, and poles
near them, and also by causing powerful electric
currents to be suddenly formed and to cease around
and about insulators in various directions, en-
deavoured to make some such state sensible, but
have not succeeded." In short, he was looking for
direct evidence of the existence of what Maxwell
called " displacement currents " — evidence which was
later found independently by the author and by
Rilntgen. And, again, there rises in his mind a
perception of that decfrofonic •'^faf.e which had
haunted his earlier researches as a something im-
posed upon the surrounding medium during the
growth or dying of an electric current.
In these years (IS35-I83S) Faraday was still in-
defaticfable in his lecture duties. In 1835 he grave
four Friday discourses, and in May and June eight
afternoon lectures at the Royal Institution on the
metals: also a course of fourteen lectures on elec-
tricity to the medical students at St. George's
INCESSANT ACTIVITIES. 167
Hospital. In 1S36 he published in the Pliilomphical
Magazine a paper on the magnetism of the metals
— notable as containing the still unverified specu-
lation that all metals would become magnetic in
the same way as iron if only cooled to a sufficiently
low temperature — and three other papers, including
one on the " passive " state of iron. He gave four
Friday discourses and six afternoon lectures on
heat. In 1837 also four Friday night discourses
and six afternoon lectures were delivered. In 1838
three Friday discourses and eight afternoon lectures
on electricity, ending in June with a distinct enun-
ciation of the doctrine of the transformations of
" force " {i.e. energy) and its indestructibility, afforded
evidence of his industry in this respect. At the same
time he was giving scientitic advice to the authorities
of Trinity House as to their lighthouses.
The laborator}^ notebook for March to August,
1838, shows a long research, occupying nearly 100
folio pages, on the relation of specific inductive
capacity to crystalline structure. This is followed
by some experiments upon an electric eel, at the
Royal Adelaide Gallery, with some unpublished
sketches of the distribution in the water of the
currents it emits. He proved, Avitli great satisfaction,
that the currents it gave were capable of producing
magnetic effects, sparks, and chemical decompo-
sition. These observations were embodied in the
fifteenth series of memoirs.
One entry in the laboratory book, ot date
April 5th, 1838, is of great interest, as showing hoAv
his mind ever recurred to the possibility of finding a
168 MICHAEL FARADAY.
connection between optical and electric phenomena :
" Must try polarized light across a crystalline di-
electric under charge. Good reasons perhaps now
evident why a non-crystalline dielectric should have
no effect."
Faraday was noAV feeling greatly the strain of
all these years of work, and in 1839 did little re-
search until the autumn. Then he returned to the
question of the origin of the electromotive force
of the voltaic cell, and by the end of the year
completed two long papers on this vexed question;
the}^ formed the sixteenth and seventeenth series,
and conclude the memoirs of this second period.
In the eighth scries, completed in April, 1884,
on the ** Electricity of the Voltaic Pile," Faraday
had dealt with the question — at that time a topic
of excited controversy — of the origin of the electro-
motive force in a cell. Volta, who knew nothing
of the chemical actions, ascribed it to the contact
of dissimilar metals, whilst Wollaston, Becquerel, and
De la Rive considered it the result of chemical
actions. The controversy has long ceased to interest
the scientitic world ; for, Avith the recognition of
the principle of the conservation of energy, it be-
came evident that mere contact cannot provide a
continuing supply of energy. It Avould now be
altogether dead but for the survival of a belief in
the contact theory on the part of one of the most
honoured veterans in science. But in the years 1834
to 1840 it was of absorbing interest. Faraday's
work quietly removed the props which supported
the older theory, and it crumbled away. He found
THE CONTACT THEORY OF ELECTRICITY. 169
that the chemical and electrical effects in the cell
were proportional one to the other, and inseparable.
He discovered a way of making a cell without any
metallic contacts. He showed that without chemical
action there was no current produced. But his re-
sults were ignored for the time. After six years
Faraday reopened the question. Again the admir-
able summary of Professor Tyndall is drawn upon
for the following account :—
The memoir on the "Electricity of the Voltaic Pile,"
published in 1834, appears to have produced but little im-
pression upon the supporters of the contact theory. These
indeed were men of too great intellectual weight and in-
,sight lightly to take up, or lightly to ahandi)n, a theory.
Faraday therefore resumed the attack in two papers com-
municated to the Royal Society on February 6 and March
19, 1840. In these papers he hampered his antagonists by
a crowd of adverse experiments. He hung difficulty after
difficulty about the neck of the contact theory, until in its
efforts to escape from his assaults it so changed its character
as to become a thing totally difi"erent from the theory pro-
posed by Volta. The more persistently it was defended,
however, the more clearly did it show itself to be a congeries
of devices, bearing the stamp of dialectic skill rather than
that of natural truth.
In conclusion, Faraday brought to bear upon it an argu-
ment which, had its full weight and purport been understood
at the time, would have instantly decided the controversy.
"The contact theory," he urged, "assumes that a force which
is able to overcome powerful resistance, as for instance that
of the conductors, good or bad, through which the current
passes, and that again of the electrolytic action where bodies
are decomposed by it, can arise out of nothing ; that without
any change in the acting matter, or the consumption of any
generating force, a current shall be produced which shall
170 MICHAKL FARADAY.
go on for ever a^^aiiist a coiiHlruit ix'Mistance, ov nuly he
■stopped, as in the voltaic trouKli, l>y the ruins which its
exertion has lieaped up in its own course. Tl)is would
indeed be ri rvado}!. of potver^ and is like no other force in
nature. We have many processes by which iha form of tlie
])()wer may be so chan;<ed, that an ;ip|);irent r<nKiu',->^t<)ii of
one into tlic other takes y^lace. So we can cha,ti;^^e chemical
force into the electric current, or the cmient into chemiral
force. The lieautifid experiments of Seebeck and Peltier
sliow tJic convertibility of heat and electricity; and others
by Oersted and myself show the convcTtibility of electricity
and magnetism. />/// /,// //o rv/.s-r, iu,l ciwn, hi, (ItoHc of the
iiyranotas <i,nd lorjicilo^ is Ihere <i pure creation or a pro-
duction of pOKX'r inith/iiit a corrcytondiiuj ('.rIi.aiislion of
Hometldng to mtpply if."
In 183!) Faraday ^;ivo five Friday disooiii's(;s and
a coLirso of oi^lit aftoriiooii lootiircs on the ]ion-
inetallic clernonts. In 1 840 ho j^^avo tlirrjo Friday
discourses and seven lectui'cs on chemical afHnily.
Ijiit in the surnnier came the serious brealcdown
alhjded to on paj^e 75. lie did no experimental work
after September 14th, nor inrleed for nearly two
years. Even tlien it was only a temporary return
to research to investig'atc the source of the electrifi-
cation produced by steam in the remarkable experi-
ments of Mr. (afterwards Lo]'d) Armstrong. He proved
it to be due to friction. 'J'his done, he continued
to rest from research luitil the middle of 1844,
thouj^di he lectured a little for the Royal Institu-
tion. In 1841 he g-ave the juvenile lectures. In
1842 he gave two Friday discourses, one of them
being on the lateral discharge in lightning-rods. He
also gave the (Jhristmas lectiu'cs on electricity.
In 1843 he gave three Friday discourses, one
END OF SECOND ACTIVE PERIOD. 171
of which was on the electricity generated by a jet
of steam ; and repeated the eight afternoon lectures
he had given in 1838. In 1844 he gave eight
lectures on heat and two Friday discourses. He
also resumed research on the condensation of gases,
and vainly tried to liquefy oxygen and hydrogen,
though he succeeded with ammonia and nitrous
oxide.
During these years of rest he also did a little
work for Trinity House, chiefly concerning light-
houses and their ventilation.
CHAPTER V.
SCIENTIFIC RKSEAllCIIES : TiiIRL) I'EKIOD.
Throughout the fruitful ten years of Faraday's
iriiddle period two magistral ideas had slowly grown
up in his mind, and as he let his thought play about
tlie objects of his daily activities, these ideas possessed
and dominated him as no newly suggested idea could
liavG done. They were tlie correlation and intcr-
convcrtibility of the forces of nature, and the optical
relations of magnetism and electricity.
During the period of enforced rest, from 18»^9 to
1844, these ideas had been ever with him. His was a
mind which during times of quiet brooding did not
cease to advance. In silence his thoughts arranged
themselves in readiness for the next period of activity,
and his work, when it began again, was all the more
fruitful for the antecedent period of cogitation.
On August 30th, 1845, Faraday for the sixth time
set to work in his laboratory to search for the con-
nection between light and electricity for which he
had so often looked, and about which he had so boldly
speculated. He began by looking for some effect
to be produced on polarised light by passing it
through a liquid which was undergoing electrolysis.
What effect precisely he expected to observe is
OPTICAL ANALYSIS. 173
unkno"\vn. Doubtless he had an open mind to per-
ceive etiects of any kind had such occurred. Earher
in the century the phenomena of polarised hght had
been worked out in great detail, through a host of
beautiful phenomena, by Arago, Biot, Brewster, and
others ; and their discoveries had shown that this
agent is capable of revealing in transparent substances
details of structure which otherwise would be quite
invisible. Placed between two Nicol prisms or two
slices of tourmaline, to serve respectively as "polariser"
and " analyser," thin sheets of transparent crystal —
selenite or mica — were made to reveal the fact that
they possessed an axis of maximum elasticity. For
when the analyser and polariser were set in the
" crossed " position, where the one would cut off
all the luminous vibrations that the other would
transmit, no light would be visible to the observer,
unless in the intervening space there were interposed
some substance endowed with one of two properties,
either that of resolving some part of the vibrations
into an oblique direction or else that of rotating the
plane of the vibrations to right or to left. If either
of these things is done, light appears through the
analyser. It is thus that structure is observed in
horn and in starch grains. It is thus that the
strains in a piece of compressed glass are made
visible. It is thus that crystalline structures gener-
ally can be studied. It is thus that the discovery was
made of the substances which possess the strange
property of twisting or rotating the plane of polar-
isation of light — namely, quartz crystal, solutions of
sugar and of certain alkaloids, and certain other
174 MICHAEL FAKADAV.
lit^uids, such as tuvpontino. Such \v;is the nij^vnt
Avliich Farada}^ proposed to euiploy to detect whether
electric forces iuipress auy quality resouibliug that ot
sfnictui'c upou transparent uiaterials.
The notes begin Avith the words : —
" I have had a glass trough uvmIo 24 inches long.
1 inch wide and about 1 h deep, in which to dectnn-
pose electrolitos and, whilst under decouiposit^ion,
along which I could pass a ray of light in ditierent
conditions and afterwards examine it."
Ho put into this trough two platinum electrodes
and a solution of sulphate of soda, but could lind no
effects. Eight pages of the notebook arc filled Avith
details all leading to negative results. For ten days
he worked at these experiuicnts with liquid electrolytes.
The substances used were distilled Avater, solution ol
sugar, dilute sulphuric Jicid, solution of sulphate
of soda (using platinum electrodes), and solution ol
sulphate of copper (using copper electrodes), The
current was sent along the ray, and perpendicular
to it in two directions at right angles with each other.
The ray was made to rotate, by altering the positi(m
of the polariser (in this case a black-glass mirror
at the proper angle), so that the plane of polarisation
might be varied. The current was used as a con-
tinuous current, as a, rapidly intermitting current, and
as a rapidly alternating induction current ; hut in no
case ivds a/ay trace of action 'pecceived.
Then he turned to solid dielectrics to see if under
electric strain they would yield any optical elfeet.
He had indeed so far back as 1838 tried the experi-
ment of coating two opposite faces of a glass cube
A DIFFICULT RESEARCH. 175
with metal foil plates that were then electrified hy a
powerful electric machine. But the experiment had
no result. This experiment he now repeats with a
score of elaborate variations, tr3'ing both crystalline
and non-crystalline dielectrics. Rock-crystal, Iceland
spar, flint glass, heavy-glass, turpentine, and air, had
a beam of polarised light passed through them, and at
the same time "lines of electrostatic tension" were,
by means of the coatings, Leyden jars, and the electric
machine, directed across these bodies, both parallel to
the polarised ray and across it, both in and across the
plane of polarisation ; but again without any visiljle
effect. Then he tries on the same bodies, and on
water, the '' tension " of a rapidly alternating induced
current, but still Avith the same negative result.
rroFessor Tyndall stated that from conversation with
Faraday, and with his faithful assistant Anderson, he
inferred that the labour expended on this preliminary
and apparently fruitless research was very great. It
occupies many pages of the laboratory notebook. That
thirty-two years later Dr. Kerr succeeded in finding
this optical effect of electrostatic strain for which
Faraday vainly sought, is no reflection upon Faraday's
powers of observation. Had there been no Faraday
there had doubtless been no discovery by Kerr.
So far the quest had been carried on either with
electric currents flowing through the transparent
sul^stance or else with mere statical electric forces,
and a whole fortnight had been spent without result.
Now another track is taken, and it leads straight
to success. He substitutes magnetic for electric
forces.
176 MICHAEL FARADAY.
" 13th Sept. 1845.
" To-day worked with lines of magnetic force,
passing them across different bodies transparent in
different directions, and at the same time passing a
polarized ray of light through them, and afterwards
examining the ray by a Nichol's Kyc-piece or otlier
means. The magnets were Electro-magnets one
l.ieing our large cylinder Electro-magnet and the
other a temporary iron core put into the helix on
a frame. This was not nearly so strong as the former.
The current of 5 cells of Grove's battery was sent
through both helices at once and the magnets were
made and unmade by putting in or stopping off* the
electric current." Air, flint-glass, rock-crystal, cal-
careous spar, were examined, but without effect. And
so he worked on through the morning, trying first
one specimen, then another, altering the directions
of the poles of his magnets, reversing tlieir polarity,
changing the position of his optical apparatus, in-
creasing the battery-power of his magnetising current
Then he bethinks him of that "heavy-glass" — the
boro-silicate of lead — which had cost him nearly four
years of precious labour during the first period of his.
MAGXETO-OPTIC DISCOVERY.
177
scientific life. The entry in the notebook is charac-
teristic.
" A piece of heavy ghiss, which was 2 inches by
rS inches and O'o of an inch thick, being a siHco-
borate of lead, was experimented Avith. It gave no
effects when the sortie magnetic poles or the contro.rij
poles Avere on opposite sides (as respects the course of
A-
EiG. 16.
the polarised ray) ; — nor when the same poles w^ere on
the same side either with -the constant or intermitting
current ; BUT when contrary magnetic poles were on
the same side there nxis o/n effect 'prodvxed on the
■poh'xrised ray, and thus magnetic force and hght were
proved to have relations to each other. This fact will
most likely prove exceedingly fertile, and of great
value in the investigation of conditions of natural
force.
" The effect was of this kind. The glass, a result
of one of my old esperiments on optical glass, had
if
178
MICHAEL FARADAY.
been exceedingly well annealed so that it did not
in any degree affect the polarized ray. The two
magnetic poles were in a horizontal plane, and the
piece of glass put up flat against them so that the
polarized ray could pass through its edges and be
exaTuined by the eye at a Nicholl's eye piece. In its
natural state the glass had no effect on the polarized
ray but on making contact at the battery so as
to render the cores N and S magnets instantly
the glass acquired a certain degree of 'power of
Fig. 17.
depolarizing the ray which it retained steadily as
long as the cores were magnets but which it lost
the instant the electric current was stopped. Hence
it Avas a permanent condition and as was expected
did not sensibly appear with an intermitting current.
"The effect was not influenced by any jogging
motion or any moderate pressure of the hands on
the glass.
'' The heavy glass had tinfoil coatings on its
two sides but when these were taken off the effect
remained exactly the same.
A mass of soft iron on the outside of the lieoxy
glass greatly diminished the effect [see Fig. 17]. . . .
" All this shcAVS that it is when the 'polarized, ray
passes parallel to the lines of magnetic ind.uction
ENOUGH FOR TO-DAY.
179
or rather to tlie direction of the magnetic curves,
that the giass manifests its power of affecting the
ray. So that the heavy glass in its magnetized
state corresponds to the cube of rock crystal : the
direction of the magnetic curves in the piece
f glass corresponding to the direction of the
optic axis in the crystal (see Exp. Researches
1689-1698). . . .
o
ElG. 18.
" Emplo3'ed our large ring electro--magnet "which
is very powerful and has of course the poles in the
right [position] only they are very close not more
than [05] of an inch apart. When the Jteavy
glass was put up against it the effect was produced
better than in any former case. . .
" Have got enough for to-day."
The description which he published in the
'' Researches " of the first successful experiment is
as follows : —
" A piece of this glass about 2 inches square
and 0-5 of an inch thick, having flat and polished
edges, was placed as a diamagnetic^ between the
^■'Faraday's definition is: — *' By a diamagnetic, I mean a body
through, which, lines of magnetic force are passing, and which
180 MICHAEL FARADAY.
poles (not as yet magnetized by the electric current),
so that the polarized ray should pass through its
length ; the glass acted as air, water, or any other
indifferent substance would do ; and if the eye-piece
[ir.. analyzer] Avere previously turned into such a
position that the polarized ray was extinguished, or
rather the iu^iage produced by it rendered invisible,
then the introduction of this glass made no alteration
in that respect. In this state of circumstances the
force of the electromagnet was developed, by sending
an electric current through its coils, and immediately
the image of the lamp-tlame became visible, and
continued so as long' as the arrang^ement continued
magnetic. On stopping the electric current, and so
causing the magnetic force to cease, the light in-
stantly disappeared ; these phasnomena could be
renewed at pleasure, at any instant of time, and
upon any occasion, showing a perfect dependence
of cause and effect."
He paused for four days in order to procure
more powerful electromagnets, for the effect which
he had observed was exceedingly slight : " A person
looking for the phicnomenon for the first time Avould
not be able to see it with a weak ]j;iagnet."
The entry in the notebook begins again : —
" ISth Sept. 1845.
" Have now borrowed and received the Woolwich
magnet."
does not by their action assume tho usual magnetic state of iron
or loadatone." It was thus a term strictly analogous to the term
(liflertric used for bodies through which lines of electric force
iiiiyht pass.
AN EXCELLENT DAY's AVr)KIv. LSI
Tills was a more powerful electromagnet tliaii
that at the Institution. With this he sets to
work with such energy that twelve pages of the
laboratory book are filled in one day. His thoughts
liad ripened during the five days, and he advanced
rapidly from point to point. The first experiment
with the Woolwich magnet brings out another point,
of which at once he grasped the significance : —
" Heavy Glass (original, or 1 74 ■^') wdien placed
thus produced a ver)- fine effect. The brightness of
the image produced rose gradually not instantl3^ due
to this that the iron cores do not take their full
intensity of magnetic state at once but require
time, and so the magnetic curves rise in intensity.
In this way the effect is one by Avhicli an optical
examination of the electromagnet can be made —
and the time necessary clearly shewn."
He next ascertains definitely that the phenomenon
is one of rotatory polarisation — that is to say, the
action of the magnet is to twist and rotate the
plane of polarisation through a definite angle de-
pending on the strength of the magnet and the
direction of the exciting current. He finds the
direction of the rotation, and verifies it by com-
parison with the ordinary optical rotation produced
by turpentine and by a solution of sugar, winding
up with the words : —
" An excellent days ivork.''
For four days he went on accunuilating proofs,
and now succeeding with the very substances with
* i.e. Specimen No. 174. Its composition was equal parts by
weight of boracic acid, oxide of lead, ujid silica.
182 MICHAEL FARADAY.
which he fonneriy failed. On September 26th he
tried the conjoint effect of a magnetic and an
electric tield. He also tried the effect of a current
running along a transparent liquid electrolyticall}^
whilst the magnet was in operation. The only re-
sults appeared to be those due to the magnet alone.
For six days in October the experiments Avere con-
tinued. He noted, as a desideratum, a transparent
oxide of iron. " With some degree of curiosity and
hope " he " put gold leaf into the magnetic lines,
but could perceive no effect." He was instinctivel}^
looking for the phenomenon which Kundt later
discovered as a property of thin transparent fibns
of iron. He entered amongst the speculative sugges-
tions in his notebook the query: "Does this [magnetic]
force tend to make iron and oxide of iron trans-
parent ? " On October 3rd he tried experiments on
light reflected from the surface of metals placed in
the magnetic field. He indeed obtained an optical
rotation by reflection at the surface of a polished
steel button, but the results were inconclusive owing
to imperfection of the surface. It was reserved for
Dr. Kerr to rediscover and follow up this effect.
On October 6th he looked for mechanical and
magnetic effects on pieces of heavy-glass and on
liquids in glass bulbs placed between the poles of
his magnet, but found none. He also looked for
possible effects of rapid motion given to the dia-
magnetic while jointly subject to the action of
magnetism and the light, but found none.
On October 11th he thinks he has got hold of
another new fact when experimenting on liquids in a
UNFULFILLED EXPECTATIONS.
183
long glass tube, the record of it tilling three pages.
But two days afterwards he finds it only a disturbing
effect due to the communication of heat to the liquid
from the surrounding magnetising coil. He seems to
regret the loss of the new fact, but adds : " As to the
other phenomenon of circular polarization, that comes
out constant, clear, and beautiful."
Then, with that idea of the correlation of forces
always in his head, there recurs to him the notion
that if magnetism or electric currents can affect a
beam of light, there must be some sort of converse
phenomenon, and that in some way or other light
must be able to electrify or to magnetise. Thirty-one
years before, when visiting Rome with Davy, he had
witnessed the experiments of Morichini on the
alleged magnetic effect of violet, light, and had
remained unconvinced. His own idea is very
different. And October 14th being a bright day with
good sunlight, he makes the attempt. Selecting a
very sensitive galvanometer, he connects it to a spiral
of wire 1 inch in diameter, 4'2 inches long, of 5Q
convolutions, and then directs a beam of sunlight
along its axis. He tries letting the beam pass
alternately through the coil while the outside is
covered, and then along the exterior while the interior
is shaded. But still there is no effect. Then he
inserts an unmagnetised steel bar within the coil, and
rotates it while it is exposed to the sun's rays. Still
there is no effect, and the sun goes down on another
of the unfultilled expectations. But had he lived to
learn of the effect of light in altering the electric
resistance of selenium discovered by Mayhew, of the
184 MICHAEL FARADAY.
Yjhotoeloctric currents discovered by I^ecqnerel, of
the discharging action of ultra-violet light discovered
by Hertz, of the revivifying effect of light on recently
demagnetised iron discovered by Ijidwell, ho would
have rejoiced that such other correlations should
have been found, tliough different from that whicli
he sought. On Xovombor ']rd ho receives a new
horseshoe rnagnet, with which he hoped to find some
optical ett'ect on air and other gases, but again
without result. That the magnetism of the earth
does actually rotate the ]jlanc of polarisation of
sky light was the discovery of Henri Becquerel so late
as 1878.
Faithful to his own maxim : " Work, finish,
publish," Faraday lost no time in writing out his
research. It was presented to the Royal Society on
November Gth, but the main result was verbally
mentioned on November 3rd at the monthly meeting
of the Eoyal Institution, and reported in the
Atkenrmi/ni of November 8th, 1845.
But even before the memoir was thus given to the
world another discovery had been made. For on
November 4th with the new magnet he repeated an
experiment which a month previously had been
Avithout result. So preoccupied was he over the new
event that he did not even go to the meeting of the
Royal Society on November 20th, when his paper on
the " Action of Magnets on Light" was read. AVhat
that new discovery was is well told by Faradiiy himself
in the letter which he sent to Professor A fie la Rive
on Hecember 4th : —
FRESH MAPtNETIC DISCOVERY. "185
[Furddaf/ to Profrxsor Avif. i.h la Rive.']
Bi'igliton, December 4, 1H4').
A[y dear FRiE>fD,— * ''I count upon you as one
uf those whose free hearts have pleasure in my success, and [
am very grateful to you for it. I have had your hist letter by
mo on my desk for several weeks, intending to ansAver it ; but
absolutely I have not been able, for of late I have shut myself
up in my laboratory and wrought, to the exclusion of every-
thing else. I heard afterwards that even your brother had
called on one of these days and been excluded.
Well, a part of this result is that which you have heard,
and iiiy paper was read to the Royal Society, 1 believe, last
Thursday, for I was not there ; and I also understand there
have been notices in the Athenceum, but I have not had time
to see them, and I do not know how they are done. However,
I can refer you to the Times of last Saturday (November 29th)
for a very good abstract of the paper. I do not know who
put it in, but it is well done, though brief. To that account,
therefore, I will refer you.
For I am still so involved in discovery that I have hardly
time for my meals, and am here at Brighton both to refresh
and work my head at once, and I feel that unless I had been
here, and been careful, I could not have continued my labours.
The consequence lias been that last ^londay I announced to
our members at the Hoyal Institution another discovery, of
which I will give you the pith iu a few words. The paper will
go to the Eoyal Society next week, and probably be read ns
shortly after as they can there find it convenient.
Many years ago I worked upon optical glass, and made a
vitreous compound of silica, Ijoracic acid, and lead, which I
will now call heavy glass, and which Amici uses in some of his
microscopes ; and it w^as this substance which enabled me first
to act on light by magnetic and electric forces. Now, if a
square bar of this substance, about half an inch tliick and two
inches long, be very freely suspended between the poles of a
powerful horse-shoe electro-magnet, immediately that the
magnetic force is developed, the bar points ; but it does not
186 MICHAEL FARADAY.
point from pole to pole, but equatorially or across the magnetic
lines of force— i.e. east and west in respect of the north and
south poles. If it be moved from this position it returns to
it, and this continues as long as the magnetic force is in action.
This efiect is the result of a still simpler action of the magnet
on the bar than what appears by the experiment, and which
may be obtained at a single magnetic pole. For if a cubical
or rounded piece of the glass be suspended by a fine thread six
or eight feet long, and allowed to hang very near a strong
magneto-electric pole (not as yet made active), then on render-
ing the pole magnetic the glass will be repelled, and continue
repelled until the magnetism ceases. This effect or power I
have worked out through a great number of its forms and
strange consequences, and they will occupy two series of the
*' Experimental Eesearches." It belongs to (til maUer (not
magnetic, as iron) without exception, so that every substance
l>elongs to the one or the other class— magnetic or diamagnetic
bodies. The law of action in its simple form is that such
matter tends to go from strong to weak points of magnetic
force, and in doing this the substance will go in either
direction along the magnetic curves, or in. either direction
across them. It is curious that amongst the metals are found
bodies possessing this property in as high a degree as perhaps
any other substance. In fact, I do not know at present
whether heavy glass, or bismuth, or phosphorus is the most
striking in this respect. I have v^xy little doubt that you
have an electro-magnet strong enough to enable you to verify
the chief facts of pointing equatorially and repulsion, if you
will use bismuth carefully examined as to its freedom from
mngnetism, and making of it a bar an inch and a half long,
and one-third or one-fourth of an inch wide. Let me, how-
ever, ask the favour of your keeping this fact to yourself for
two or three weeks, and preserving the date of this letter as a
record. I ought (in order to preserve the respect due to the
Royal Society) not to write a description to anyone until the
l^aper has been received or even read there. After three
weeks or a month I think you may use it, guarding, as I am
sure you will do, my right.
MAGNETIC EXPERIMENTS. 187
And now, my dear friend, I mu.st conclude, and hasten to
work again. But first give my kindest respects to Madame de
la Rive, and many thanks to your brother for his call.
Ever your obedient and affectionate friend,
M. Far.'VDAy.
The discovery of diamagnetisni which Faraday
thus announced was in itself a notable achievement.
As Tyndall points out, the discovery itself was in all
probability due to Faraday's hal.tit of not regarding
as final any negative result of an experiment until he
had brought to bear upon it the most powerful
resources at his command. He had tried the effects of
ordinary magnets on brass and copper and other
materials commonly considered as non-magnetic.
But when, for the purpose of the preceding research
on the relation of magnetism to light, he had
deliberately procured electromagnets of unusual
power, he again tried what their effect might be upon
non-magnetic stuffs. Suspending a piece of his
heavy glass near the poles in a stirrup of writing-
paper slung upon the end of a long thread of cocoon
silk, he found it to experience a strong mechanical
action when the magnet was stimulated by turning
on the current. His precision of description is
characteristic : —
I shall have such frequent occasion to refer to two chief
positions of position across the magnetic field, that, to avoid
periphrasis, I will here ask leave to use a term or two
conditionally. One of these directions is that from pole to
pole, or along the lines of magnetic force, I will call it the
axial direction ; the other is the direction perpendicular to
this, and across the line of magnetic force and for the time,
1>^H MICHAEL FAIIADAY.
and as respects the space between the poles, I will eiill it the
e'luaiorial direction.
Xote the occurrence in the above passage for the
first tune of the term " the magnetic field."' Faraday's
description of the discover)' continues as follows : —
The bar of silicated borate of lead or heavy glass already
described as the substance in which magnetic forces were first
made effectually to bear on a ray of light, and which is 2
inches long, and about O'") inch wide and thick, Avas suspended
centrally between the magnetic poles, and left until the effect
of torsion was over. The magnet was then thrown into action
-^m
WW
Fig. 19.
by making contact at the voltaic battery. Immediately the
bar moved, turning round its point of suspension, into a
position across the magnetic curve or line of force, and, after a
few vibrations, took up its place of rest there. On being
displaced by hand from this position it returned to it, and
this occurred many times in succession.
Either end of the bar indifferently went to either side of
the axial line. The determining circumstance was simply
inclination of the bar one way or the other to the axial line at
the beginning of the experiment. If a ]),irticular or marked
end of the bar were on one. side of the magnetic or axial
line when the magnet was rendered active, that end went
further outwards until the bar had taken up the equatorial
position. . . .
Here, then, we have a magnetic bar which points east
and west in relation to north and south poles — i.e. points
perpendicularly to the lines of magnetic force. . . .
DIAMAGNETIC LAWS. 189
To produce these effects of pointing across the magnetic
carves, the form of the heavy glass must be long. A cube or
a fragment approaching roundness in form will not point; but
a long piece will. Two or three rounded pieces or cube.-:;,
placed side by aide in a paper tray, so as to form an oblong
accumulation, .will also point.
Portions, however, of any form are repelled ; so if two
pieces be hung up at once in the axial line, one near each pole,
they are repelled by their respective j)oles, and approach,
seeming to attract each other. Or if two pieces be hung
up in the equatorial line, one on each side of the axis,
then they both recede from the axis, seeming to repel each
other.
From the little that has been said, it is evident that the
bar presents in its motion a complicated result of the force
exerted by the, magnetic power over the heavy glass, and that
when cubes or spheres are employed a much simpler indication
of the effect may be obtained. Accordingly, when a cube was
thus used with the two poles, the eS'ect was repulsion or
recession from either pole, and also recession from the magnetic
axis on either side.
So the indicating particle would move either along the
magnetic curves or across them, and it w^ould do this either in
one direction or the other, the only constant point being that
its tendency was to move from stronger to weaker places of
magnetic force.
This appeared much more simply in the case of a single
magnetic pole, for then the tendency of the indicating cube or
sphere was to move outwards in the direction of the magnetic
lines of force. The appearance was remarkably like a case of
weak electric repulsion.
The cause of the pointing of the bar, or any oblong
arrangement of the heavy glass, is now evident. It is merely
a result of the tendency of the particles to move outwards, or
into the positions of weakest magnetic action.
When the bar of heavy glass is immersed in water,
alcohol, or yether, contained in a vessel between the poles, all
190 MICHAEL FARADAY.
the preceding effects occur— the h^v points and the cube
recedes exactly ia the same manner as in air.
The effects ei^ually occur in vessels of \vood, stone, eartb,
copper, lead, silver, or any of those substances which belong to
the diamagnetic class.
I have obtained the same equatorial direction and
motions of the heavy glass bar as those just described, but
in a very feeble degree, by the use of a good common steel
horseshoe magnet.
Then he goes on to enumerate the many bodies of
all sorts : crystals, powders, liquids, acids, oils ; organic
bodies such as wax, olive-oil, wood, beef (fresh and
dry), blood, aj^ple, and bread, all of which were found
to be dianiacrnetic. On this he remarks : —
o
It is curious to see such a list as this of bodies presenting
on a sudden this remarkable property, and it is strange to find
a piece of Avood, or beef, or apple, obedient to or repelled by a
magnet. If a man could be suspended with sufficient delicacy
after the manner of Dufay, and placed in the magnetic field,
he would point ecjuatorially, for all the substances of which he
is formed, including the blood, possess this property.
A few bodies were found to be feebly magnetic,
including paper, sealing-wax, china ink, asbestos,
fluorspar, peroxide of lead, tourmaline, plumbago,
and charcoal. As to the metals, he found iron,
cobalt, and nickel to stand in a distinct class. A
feeble magnetic action in platinum, palladium, and
titanium was suspected to be due to traces of iron in
them. Bismuth proved to be the most strongly
diamagnetic, and was specially studied. The repellent
effect between bismuth and a magnet had indeed
been casually observed twice in the prior history of
THE MAGNETIC BRAKE. 191
science, first by Bnigmans, then by Le Baillif.
Faraday, with chai\a,cteristic frankness, refers to his
having a "vague impression" that the repulsion of
bismuth by a magnet had been observed before,
though unable at the time of writing to recollect any
reference. His own experiments ran over the whole
range of substances, however, and demonstrated the
universal existence in greater or less degree of this
magnetic nature. Certain differences observed be-
tween the behaviour of bismuth and of heavy glass
on the one hand, and of copper on the other hand,
though all are diamagnetic, led him to note and
describe some of the pseudo-diamagnetic effects which
occur in copper and silver, in consequence of the
induction in them of eddy-currents, from which heavy-
glass and bismuth are, by their inferior electric
conductivity, comparatively free. He described the
beautiful and now classical experiment of arresting,
by turning on the exciting current, the rotation of
a copper cylinder spinning between the poles of an
electromagnet.
Faraday continued to prosecute this newest line of
research, and at the end of December, 1845, presented
another memoir (the twenty-first series of the Experi-
mental Researches) to the Eoyal Society. He had
now examined the salts of iron, and had found that
every salt and compound containing iron in the basic
part was magnetic, both in the solid and in the liquid
state. Even prussian-blue and green bottle-glass
were magnetic. The solutions of the salts of iron
were of special importance, since they furnish the
means of making a magnet which is for the time
192 MICHAEL FARADAY.
liquid, transparent, and, within certain linnts, adjust-
able in strength. His next step was to examine how
bodies beha"\-ed when innnersed in some surrounding
medium. A Aveo.k sokition of iron, enclosed in a ver}-
thin glass tube, though it pointed axially when hung
in air, pointed equatorially when immersed in a
stronger solution. A tube full of air pointed axially,
and was attracted as if magnetic when surrounded
with w^ater. Substances such as bismuth, copper, and
phosphorus are, hoAvever, highly diamagnetic w^hen
suspended in vacuo. Such a view would n:ia'ke viere
space magnetic. Hence Faraday inclined at first to
the opinion that diamagnetics had a specific action
antithetically distinct from ordinary magnetic action.
SeA'eral times he pointed out that all the phenomena
resolve themselves simply into this, that a portion of
such matter as is termed diamagnetic tends to move
from stronger to places or points of weaker force in
the mametic field. He does, indeed, hazard the
suggestion that the phenomena might be explained
on the assumption that there was a sort of diamag-
netic polarit}- — that magnetic induction caused in
them a contrar}^ state to that which it produced in
ordinary magnetic inatter. But his own experi-
ments failed to support this view, and, in oppo-
sition to Weber and Tyndall, he maintained
afterwards the non-polar nature of diamagnetic
action.
In 1846 Faraday gave two Friday night discourses
on these magnetic researches, one on the cohesive
force of water, and one on Wheatstone's electro-
magnetic chronoscope. At the conclusion of the
THOUGHTS ON KAY VIBRATIONS. 198
last-named he said that he was induced to utter a
specuhition which had long been gaining strength in
his mind, that perhaps those vibrations by which
radiant energies, such as light, heat, actinic rays, etc.,
convey their force through space are not mere
vibrations of an rether, but of the lines of force which,
in his view, connect different masses, and so Avas
inclined, in his own phrase, " to dismiss the aether."
In one of his other discourses he made the suggestion
that we might " perhaps hereafter obtain magnetism
from light."
The speculation above referred to is of such
intrinsic importance, in view of the developments of
the last decade, that it compels further notice.
Faraday hims'elf further expanded it in a letter to
Richard Phillips, which Avas printed in the Philo-
sophical Magazine for May, 1846, under the title
" Thoughts on Ray- vibrations." In this avowedly
speculative paper Faraday touched the highest point
in his scientific writings, and threw out, thouo-h in a
tentative and fragmentary way, brilliant hints of that
which his imagination had perceived, as in a vision ;
— the doctrine now known as the electromagnetic
theory of light. At the dates when the earlier
biographies of Faraday appeared, neither that doctrine
nor this paper had received the recognition due to its
importance. Tyndall dismisses it as "one of the
most singular speculations that ever emanated from
a scientitic man." Bence Jones just mentions it in
half a line. i)r. Gladstone does not allude to it. It
therefore seems expedient to give here some extracts
from the letter itself: —
N
194 MICHAEL FARADAY,
THOUGHTS ON RAY- VIBRATIONS.
To Rlchnrd Phillips, Esq.
Dear Sir,— At your request, I will endeavour to convey
to you a notion of that which I ventured to say at the close
of the last Friday evening meeting f. . . ; but, from firs
to last, understand that I merely threw out, as matter for
speculation, the vague impressions of my mind, for I gave
nothing as the result of sufficient consideration, or as the
settled conviction, or even probable conclusion at which I had
arrived.
The point intended to be set forth for the consideration
of the hearers was whether it was not possible that the
vibrations— which in a certain theory are assumed to account
for radiation and radiant phenomena — may not occur in the
lines of force which connect particles, and consequently
masses, of matter together — a notion which, as far as it is
admitted, will dispense with the iether, which, in another
view, is supposed to be the medium in which these vibra-
tions take place.
Another consideration bearing conjointly on the hypo-
thetical view, both of matter and radiation, arises from the
comparison of the velocities with which the radiant action and
certain powers of matter are transmitted. The velocity of
light through space is about 190,000 miles* a second. The
velocity of electricity is, by the experiments of Wheatstone,
shown to be as great as this, if not greater. The light is
supposed to be transmitted by vibrations through an aether
which is, so to speak, destitute of gravitation, but infinite in
elasticity ; the electricity is transmitted through a small
metallic wire, and is often viewed as transmitted by vibrations
also. That the electric transference depends on the forces or
powers of the matter of the wire can hardly be doubted when
* Subsequent investigation has reduced this figure to about
186,400 miles per second, or about 30,000,000,000 centimetres per
second.
LATEKAL VIBRATIONS. 195
we consider the different conductibility of the various metallic
and other bodies, the means of afFectinf^ it by heat or cold, the
way in which conducting bodies by combination enter into the
constitution of non-conducting substances, and the contrary,
and the actaal existence of one elementary body (carbon) both
in the conducting and non-conducting state. The power of
electric conduction, being a transmission of force equ;d in
velocity to that of ligbt, appears to be tied up in and
dependent upon the properties of the matter, and is, as it
were, existent in them.
In experimental philosophy we can, by the phenomena
presented, recognise various kinds of lines of force. Thus
Fig. 20.
there are the lines of gravitating force, those of electrostatic
induction, those of magnetic action, and others partaking of a
dynamic character might be perhaps included. The lines of
electric and magnetic action are by many considered as
exerted through space like the lines of gravitating force. For
my own part, I incline to believe that when there are inter-
vening particles of matter— being themselves only centres o
force — they take part in carrying on the force through the
line, but that when there are none the line proceeds through
space. Whatever the view adopted respecting them may be,
we can, at all events, affect these lines of force in a manner
which may be conceived as partaking of the nature of a shake
or lateral vibration. For suppose two bodies, a b, distant
from each other, and under mutual action,* and therefore
* The accompanying diagram (Fig. 20) waa not given by Fara-
day. It was pencilled by the author more than twenty years ago in
the margin of his copy of Faraday's ''Experimental Researches," vol.
iii., p. 450, opposite this passage.
196 MICHAEL FARADAY.
connected by lines of force, and let us fix our attention upon
one resultant of force liavint; an invariable direction as regards
space ; if one of the bodies move in the least degree right or
left, or if its power be shifted for a moment within the mass
(neither of these cases being difficult to realise if a or b be
either electric or magnetic bodies), then an eflect ecinivalent to
a lateral disturbance will take place in the resultant upon
which we are fixing our attention, for either it will increase
in force whilst the neighbouring resultants are diminishing,
or it will fall in force while they are increasing.
The view which 1 am so bold as to put forth considers,
therefore, radiation as a high species of vibration in the lines
of force which are known to connect particles, and also masses,
of matter together. It endeavours to dismiss the ;tther, but
not the vibrations. The kind of vibration which, I believe,
can alone account for the wonderful, varied, and beautiful
phenomena "of polarisation is not the same as that which
occurs on the surface of disturbed water or the waves of sound
in gases or liquids, for the vibrations in these cases are direct,
or to and from the centre of action, whereas the former are
lateral. It seems to me that the resultant of two or more
lines of force is in an apt condition for that action, which may
be considered as ec[uivalent to a lateral vibration ; whereas a
uniform medium like the a?ther does not appear apt, or more
apt than air or water.
^The occurrence of a change at one end of a line of force
easily suggests a consequent change at the other. The
propagation of light, and therefore probably of all radiant
action, occupies time ; and that a vibration of the line of force
should account for the phenomena of radiation, it is necessary
that such vibration should occupy time also.
And now, my dear Phillips I must conclude. I do not
think I should have allowed these notions to have escaped
from me had I not been led unawares, and without previous
consideration, by the circumstances of the evening on which
THE 8HAD0W OF A SPECULATION. 197
I had to appear suddenly * and occupy the place of another.
Now that I have put them on paper, I feel that I ought to
have kept them much longer for study, consideration, and
perhaps final rejection ; and it is only because they are sure
to go abroad in one way or another, in consequence of their
utterance on that evening, that I give them a shape, if shape
it may be called, in this rei)ly to your in([uiry. One thing is
certain, that any hypothetical view of radiation which is likely
to be received or ret;uned as satisfactory must not much
longer comprehend alone certain phenomena of light, but must
include those of heat and of actinic intluence also, and even
the conjoined phenomena of sensible heat and chemical power
produced by them. In this respect a view which is in some
degree founded upon the ordinary forces of matter may
perhaps find a little consideration amongst the other views
that will jirobably arise. I think it likely that I have made
many mistakes in the preceding pages, for even to myself my
ideas on this point appear only as the shadow of a speculation,
or as one of those impressions on the mind which are allowable
for a time as guides to thought and research. He who labours
in exjierimental inquiries knows how numerous these are, and
how often their apparent fitness and beauty vanish before the
progress and development of real, natural truth.
I am, my dear Phillips,
Ever truly yours,
Roi/al Listitufion, M. Faraday.
April 15, 1846.
If it be thought that too high ca value has here
been set upon a document which its author
himself only clauned to be " the shadow of a
speculation," let that value be justified out of the
* The discourse was to have been dehvered by Wheatstone him-
self, who, however, at the last moment, overcome by the shyness from
which he siifiered to an almost morbid degree, quitted the Institution,
and left the delivery of the discourse to Faraday.
19s MICHAEL FARADAY.
mouth of the man who ei^c^hteen years later enriched
the world Avith the mathematical theory of the pro-
pagation of electric waves, the late Professor Clerk
Maxwell. In 18G4 he published in the Philosophical
Transactions a "Dynamical Theory of the Electro-
magnetic Field/' in which the following passages
occur : —
We have therefore reason to believe, from the phenoinena
of light and heat, that there is an irthereal medium filling
space and permeating bodies capable of being set in inotion,
and of transmitting that motion to gross matter, so as to heat
it and afteet it in various ways. . . . Hence the parts of
tliis medium must be so connected that the motion of one part
depends in some waj^ on the motion of the rest ; and at the
same time these connections must be capable of a certain kind
of elastic yielding, since the communication of motion is not
instantaneous, but occupies time. The medium is therefore
capable of receiving and storing up two kinds of energy —
namely, the "actual" energy depending on the motion of its
parts, and "potential" energy, consisting of the work which
the medium will do in recovering from displacement in virtue
of its elasticity.
The propagation of undulations consists in the continual
transformation of one of these forms of energy into the other
alternately, and at any instant the amount of energy in the
whole medium is equ;illy divided, so that half is energy of
motion and half is elastic resilience.
In order to bring these results within the power of
symbolic calculation, I then express them in the form of the
general equations of the electromagnetic field.
The general equations are next applied to the case of a
magnetic disturbance propagated through a non conducting
field, and it is shown that the only disturbances which can be
so propagated are those Avhich are transverse to the direction
ELECTKOMAGNETIC THEORY OF LIGHT. 199
of propagation, and that the velocity of propagation is the
velocity v, found from experiments such as those of Weber,
which expresses the number of electrostatic units of electricity
which are contained in one electromagnetic unit. This velo-
city is so nearly that of light, that it seems we have strong
reason to conclude that light itself (including radiant heat and
other radiations, if any) is an electromagnetic disturbance in
the form of waves propagated through the electromagnetic
field according to electromagnetic laws. . . . Conducting
media are shown to absorb such radiations rapidly, and there-
fore to be generally opaque.
The conception of the propagation of transverse magnetic
disturbances to the exclusion of normal ones is distinctly set
forth by Professor Faraday in his " Thoughts on ftay Vibra-
tions." The 'electromagnetic theory of light, as j'f'i^oposed by
him, is the same in substance as that which I have begun to
develop in this paper, ^ except that in 184G there Avere no data
to calculate the velocity of propagation.
During the rest of this year (1846) and the next
Faraday did very little research, though he continued
his Royal Institution lectures and his reports for
Trinity House. Amongst the latter in 1847 was one
on a proposal to light buoys by incandescent electric
lamps containing a platinum wire spiral. He was
compelled, indeed, to rest by a recurrence of brain
troubles, giddiness, and loss of memory. Honours
however, continued to be heaped upon him both
abroad and at home, as the following extract from
Bence Jones shows : —
In 1846, for his two great discoveries, the Rumford and
the Royal Medals were both awarded to him. This double
honour will probably long be unique in the annals of the
*■ TJie italics hero are mine. S, P. T,
200 MICHAEL KARA HA V.
luiyal Society. In former years he had ahvady received tlie
Copley and Royal Medals for his experimental discoveries.
As his medals increased it became remarkable that he— who
kept his diploma-book, his portraits and letters of scientific
men, and everything he had in the most perfect order— seemed
to take least care of his most valnable rewards. Tliey were
locked up in a box, and mi»;ht have ]iassed for old iron.
Probably he thoui:jht, as others di*l afterwards, that their
value, if seen, might lead to their loss.
BetAveen the t>v en ty- first and tw'onty-second series
of '^ Experimental Researehes " nearl}^ three years
elapsed. In the autmnn of 184S the matter -which
claimed investigation was the pecnliar behavionr ot
bismuth in the mametic field. Certain anomalies
were observed wdiich were finally traced to tlic
crystalline nature of the metal, for it appeared that
wdien in that state the crystals themseh^es — to adopt
modern phraseology — showed a g^reater magnetic
permeability in a direction perpendicular to their
planes of cleavage than in any direction parallel to
those planes. Hence when a crystalline fragment
was hung in a uniform- nuignetic field (Avhere the
dianuxgnetic tendenc}^ to move from a strong to a
weak region of the field "was eliminated), it tended to
point in a determinate direction. Faraday expressed
it that the structure of the crystal showed a certain
'' axiality," and he regarded these eflects as preseiitinc^
evidence of a " magnecrystallic " force, the law of
action being that the lino or axis of magnecrystallic
force tended to phice itself parallel to the lines of the
magnetic field in "which the crystal was placed.
Arsenic, antimony, and other crystalline metals were
CRYSTALLINE F(^KCE8. 201
sitiiilarly examined. The subject Avas an intricate
one, and there are frequent obscurities in the phrase-
ology tentatively adopted for explaining the phe-
nomena. In one place Faraday rather pathetically
laments his imperfect mathematical knowledge. This
seems like an echo of his inability to follow the
analytical reasoning of Poisson, who, starting from a
hypothesis about the supposed " magnetic fluids "
being movable within the particles of a body,
supposing that these particles were non-spherical and
were symmetrically arranged, had predicted (in 1827)
that a portion of such a substance would, when
brought into the neighbourhood of a magnet, act
differently, according to the different positions in
which it might be turned about its centre. But this
very inability to follow Poisson's retined analysis gave
a new direction to Faraday's thoughts, and caused
him to conceive the idea of magnetic permeabilities
differing in different directions, an idea which, as
Sir Wilham Thomson (the present Lord Kelvin)
showed in 1851,* is equally susceptible of mathe-
matical treatment by appropriate symbols. Lord
Kelvin has also spoken (crp. ciL, p. 484) of the
matter as follows : " The singular combination of
■■■ It is light to add that -what, according- to the thuory explained
in the text, must be the correct explanation of the peculiar phenomena
of magnetic induction depending on magnecrystallic properties was
clearly stated in the form of a conjecture hy Faraday in his t\vent\'-
second series in the following terms: 'M^r we might suppose that
the crystal is a little more apt for magnetic induction, or a httle less
apt for diamagnetic induction, in the direction of the magnecrystallic
axis than in other directions" (Sir "William Thomson, Philosophical
Mr/f/azipc, 1851, or " Papers on Electrostatics and Magnetism," p. 47G).
202 MICHAEL FARADAY.
mathematical acuteness -with experimental research
and profound ph3^sical speculation which Faraday,
though not a 'mathematician,' presented is remark-
abl}^ illustrated by his use of the expression ' conduct-
ing 'poivev of a m.af/netic vied mvi for lines of force/''
Tyndall has given a succinct summary of these
researches — in Avhich also he took a part — from
which the following extract must suffice : —
And here follows one of those expressions which charac-
terise the conceptions of Faraday in regard to force gener-
ally : "It appears to me impossible to conceive of the results
in any other way than by a mutual reaction of the magnetic
force, and the force of the particles of the crystal u])on e:ich
other." He proves that the action of the force, though thus
molecular, is an action at a distance. He shows that a
bismuth crystal can cause a freely-suspended magnetic needle
to set parallel to its magnecrystallic axis. Few living men are
aware of the difficulty of obtaining results like this, or of the
delicacy necessary to their attainment. "But though it thus
takes up the character of a force acting at a distance, still it is
due to that power of the ]>articles which makes them cohere in
regular order and gives the mass its crystalline aggregation,
and so often spoken of as acting at insensible distances." Thus
he broods over this new force, and looks at it from all points
of inspection. Experiment follows experiment, as thought
follows thought. He will not relinquish the subject as long as
a hope exists of throwing more light upon it. He knows full
well the anomalous nature of the conclusion to which his
experiments lead him. But experiment to him is final, and he
will not shrink from the conclusion. "This force," he says,
"appears tome to be very strange and striking in its character.
It is not polar, for there is no attraction or repulsion." And
then, as if startled by his own utterance, he asks : "What is
the nature of the mechanical force which turns the crystal
round and makes it affect a magnet?" , . . "I do not
MAGNETISM AND CRYSTALLISATION. 203
remember," he continues, "heretofore such a case of force as
the present one — Avhere a l>ody is brought into position only
without attraction or repulsion."
Plucker, the celebrated j;^eometer already mentioned, who
pursued experimental physics for many years of his life with
singular devotion and success, visited Faraday in those days,
and repeated before him his beautiful experiments on magneto-
optic action. Faraday repeated and verified Pliicker's observa-
tions, and concluded, Avhat he at first seemed to doubt, that
Pliickers results and magnecrystallic action had the same
origin.
At the end of his papers, when he takes a last look along
the line of I'esearch, and then turns his eyes to the future,
utterances quite as much emotional as scientific escape from
Faraday. "I cannot," he says at the end of his first paper on
magnecrystallic action, "conclude this series of researches
Avithout remarking how rapidly the knowledge of molecular
forces grows upon us, and how strikingly every investigation
tends to develop more and more their importance and their
extreme attraction as an object of study. A few years ago
magnetism was to us an occult power, affecting only a few
bodies. Now it is found to inliuence all bodies, and to possess
the most intimate relations with electricity, heat, chemical
action, light, crystallisation, and through it with the forces
concerned in cohesion. And we may, in the present state of
things, well feel urged to continue in our labours, encouraged
by the hope of bringing it into a bond of union with gravity
itself."
In 1848 Faraday gave five Friday night discourses,
three of them on the *'Diamagnetic Condition of
Flarne and Gases." In 1849 he gave tAvo, one of
them on Pliicker's researches. In 1850 he gave
two, one of them being on the electricity of the
air, the other on certain conditions of freezing
water. He had meanwhile continued to work at
magnetism. The twenty-third series dealt with the
204 MICHAEL FARADAY.
supposed diamagnetic polarity. It incidentally dis-
cussed the distortion produced in a magnetic field by
a mass of copper in motion across it. The twenty-
fourth series was on the possible relation of gravity
to electricity. The paper concludes with the words :
" Here end my trials for the present. The results are
negative. They do not shake my strong feeling of
the existence of a relation between gravity and
electricity, though they give no proof that such a
relation exists." The next series (the twenty-fifth)
was on the *' Non-expansion of Gases by Magnetic
Force " and on the " Magnetic Characters of Oxygen
[Avhich he had found to be highly magnetic], Nitrogen,
and Space." He had found that magnetically sub-
stances must be classed either along with iron and
the materials that point axially, or else with bismuth
and those that point equatorially, in the magnetic
field. The best vacuum he could procure he regarded
as the zero of these tests ; but before adopting it as
such, he verified by experiment that even in a
vacuum a magnetic body still tends from weaker to
stronger places in the magnetic field ; Avhile diamag-
netic bodies tend from stronger to weaker. He then
says Ave must consider the magnetic character and
relation of sjKtce free from any material substance.
" Mere space cannot act as matter acts, even though
the utmost latitude be allowed to the hypothesis of
an ether." He then proceeds as follows : —
Now that the true zero is obtained, and the great variety
of material subj^^tances satisfactorily divided into two general
classes, it appears to me that we want another name for the
magnetic class, that we may avoid confusion. The word
MORE NKW WOEDS. 205
magnetic ought to be general, and include all the phenom-
ena and effects produced by that power. But then a word
for the subdivision opposed to the diamagnetic cla.ss is
necessary. As the language of this branch of science may
soon require general and careful changes, I, assisted by a kind
friend, have thought that a word — not selected with particular
care — might be provisionally useful ; and as the magnetism
of iron, nickel, and cobalt when in the magnetic field is like
that of the earth as a whole, so that when rendered active
they place themselves parallel to its axes or lines of magnetic
force, I have supposed that they and their similars (includ-
ing oxygen now) might be called paramagnetic bodies, giving
the following division : —
(.diamagnetic.
The " kind friend" alluded to was Whewell, as the
following letter shows : —
[Hev. W. Whewell to M. Faraday.]
July, 1850.
I am always glad to hear of your wanting new ivords,
because the want shows that you are pursuing new thoughts
— and your new thoughts are worth something — but I always
feel also how difficult it is for one who has not pursued the
train of thought to suggest the right word. There are so
many relations involved in a new discovery, and the word
ought not glaringly to violate any of them. The purists would
certainly object to the opposition, or co-ordination, of ferro-
magnetic and diamagnetic, not only on account of the want of
symmetry in the relation oi ferro and dia, but also because the
one is Latin and the other Greek. . . . Hence it would
appear that the two classes of magnetic bodies are those which
place their length ■parallel, or according, to the terrestrial
magnetic lines, and those which place their length transverse
to such lines. Keeping the preposition dia for the latter, the
preposition para, or ana, might be used for the former.
Perhaps pjara would be best, as the word parallel, in which
it is involved, would be a technical memory for it. ... I
206 MICHAEL FARADAY.
rejoice to hear that you have new views of discovery opening
to you. I always rejoice to hail the light of such Avhen they
dawn upon you.
The twenty-sixth series of researches opened with
a consideration of magnetic " conducting power," or
permeability as we should now^ term it, and then
branched oti' into a lengthy discussion of atmospheric
magnetism. The subject was continued through the
twenty - seventh series, which was completed in
November, 1850. The gist of this is summed up in
one of his letters to Schonbein : —
Roj^al Institution, November 19, 1850.
Mv PEAR ScHoXBErx,— I Avish I could talk with you,
instead of being obliged to use pen and paper. I have fifty
matters to speak about, but either they are too trifling for
writing, or too important, for what can one discuss or say
in a letter ? ... By the bye, I have been working with
the oxygen of the air also. You remember that three years
ago I distinguished it as a magnetic gas in ray paper on
the diiunagnetism of flame and gases founded on Bancalari's
experiment. Now I find in it the cause of all the annual and
diurnal, and many of the irregular, variations in the terrestrial
magnetism. The observations made at Hobarton, Toronto,
Greenwich, St, Petersburg, "Wasliington, St. Helena, the Cape
of (jood Hope, and Singapore, all appear to me to accord with
and support my h5q)othesis. I will not pretend to give you
an account of it here, for it would require some detail, and
I really am weary of the subject. I have sent in three long
papers to the lloyal Society, and you shall have copies of them
in due time. . . .
Ever, my dear Schonbein, most truly yours,
M. Faraday.
While writing out these researches for the Royal
Society, he had been sta3dng in Upper Norwood. He
PAl^EKS TO liE LET LOOSE. 207
Avrote thus of himself to Miss Moore at the end of
August : —
We have taken a little house here on the hill-top, where I
have a small room to myself, and have, ever since we came
here, been deeply inmiersed in magnetic cogitations. I write,
and write, and write, until three pujiers for the Iloyal Society
are nearly completed, and I hope that two of them will be
good if they justify my hopes, for I have to criticise them
again and again before I let them loose. You shall hear of
them at some of the Friday evenings. At present 1 must not
say more. After writing, I walk out in the evening, hand-in-
hand with my dear wife, to enjoy the sunset ; -for to me, who
love scenery, of all that I have seen or can see there is none
surpasses that of Heaven. A glorious sunset brings with it a
thousaml thoughts that delight me."
To De la Rive he wrote later as follows : —
[M. Faraday to A. <.h la Rive.']
Royal Institution, February 4, 185L
My dear De la Eive, — My wife and I were exceedingly
sorry to hear of your sad loss. It brought vividly to our
remembrance the time when we were at your house, and you,
and others with you, made us so welcome. What can we say
to these changes but that they show by comparison the vanity
of all things under the sun '? I am very glad that you have
sjiirits to return to work again, for that is a healthy and
proper employment of the mind under such circumstances.
With respect to my views and experiments, I do not
think that anything shorter than the papers (and they will run
to a hundred pages in the "Transactions") will give you
possession of the subject, because a great deal depends upon
the comparison of observations in dhl'erent parts of the world
with the facts obtained by experiment, and with the deduc-
tions drawn from them ; but I will try to give you an idea of
the root of the matter. You are aware that I use the ])hrase
20s MICHAEL FARADAY.
line nr )ii<K/nefic f<i,ct\ to reiu'esent tlie iiror^enoe of magnetic
force, ami the direction (of iiolarity) in which it is exerted ;
and by the idea >vhich it conveys one obtains vitv weil, and I
believe without error, a notion of the distribution of the forces
about a liar-niaiinet, or between near Hnt ^oles itresenting' a
field of equal force, ov in any other case. Xow, if circum-
stances be arranged so as to present a field of equal force,
which is easily done, as I have shown by the electro-magnet,
then if a s]there of iron or nickel be ]ilaced in the field, it
inimedi;itely disturbs the direction of the lines of force, fur
they are concentrated a\ ithiu the sjiheve. They are, however,
not merely concentrated, but co)iforteJ, for the sum of forces
in any one section across the field is always equal to the .sum
of forces in any other section, and therefore their condensation
in the iron or nickel cannot occur without this contortion.
Moreover, the contortion is easily shown by using a small
needle (one-tenth of an inch k'>ng) to examine the lield, for, :is
before the introduction of the s]>here of iron or nickel, it
would always take ujt a itosition luirallel to itself. After-
wards it varies in position in different jilaces near the sphere.
This being understood, let us then suppose the sphere to be
raised in temjierature. At a certain temperature it begins to
lose its jiower of ati'ecting the lines of magnetic force, and ends
by retaining scarcely any. So that as regards the little needle
mentioned above, it now stands everywhere parallel to itself
Avithin the field of force. This change occurs with iron at a
very high temperature, and is passed through within the
compass, ajiparently, of a small number of degrees. Witli
nickel it occurs at much lower temj^eratures, being atiected by
the heat of boiling oil.
Xow take another step. Oxygen, as I showed above,
three years ago in the Philosophical Magazine for 1S47, vol.
xxxi., i)p. 4Ut, 415, 4U), is magnetic in relation to lutrogen and
other gases. E. Beccjuerel, without knowing of my results,
has confirmed and extended them in his jiaper of last year,
and given certain excellent measures. In my pajter of 1847
I showed also that oxygen (like iron and nickel) lost its
magnetic power and its ability of being attracted by the
ATMOSPHERIC MAGNETISM. 209
mugnet Avhen heated (]i. 417). And I further showed that the
temperature.s at Avhich this took place were within the rant;-c
of common temperature, for the oxygen of the air — i.e. the air
altogetlier — is increased in magnetic power when cooled to
O"^ F. (]L 406). Now I mu.st refer you to the pajiers themselves
for the (to me) strange results of the incompressibility
(magnetically speaking) of oxygen and the inexpansibility of
nitrogen and other gases ; for the description of a differential
balance by which I can compare gas with gas, or the same
gas at ditferent degrees of rarefaction ; for the determination
of the true zero, or point between magnetic and diamagnetic
bodies ; and for certain views of magnetic conduction and
l)ularity. You will there find described certain very delicate
experiments upon diamagnetic and very weak magnetic bodies
concerning their action on each other in a magnetic held of
equal force. The magnetic bodies repel each other, and the
diamagnetic bodies repel each other ; but a magnetic and a
diamagnetic body attract each other. And these results,
combined with the qualities of oxygen as just described,
convince me that it is able to deflect the lines of magnetic
force passing through it just as iron or nickel is, but to an
infinitely smaller amount, and that its power of deflecting
the lines varies with its temperature and degree of rarefaction.
Then comes in the consideration of the atmosphere, and
the manner in which it rises and falls in temperature by the
presence and absence of the sun. The place 6i the great warm
region nearly in his neighbourhood ; of the two colder regions
which grow up and diminish in the northern and southern
hemispheres as the sun travels between the tropics; the elfect
of the extra warmth of the northern hemisphere over the
southern ; the effect of accumulation from the action of
preceding months ; the effect of dip and mean declination at
each particular station ; the effects that follow from the non-
coincidence of magnetic and astronomical conditions of
])olarity, meridians, and so forth ; the results of the distribu-
tion of land and water for any given place— for all these and
many other things I must refer you to the papers. T could
not do them justice in any account that a letter could contain,
O
210 MICHAEL FARADAY.
and sliOLild run the risk of leading' you into error regarding
them. But I may say that, deducing from the experiments
and the theory what are the deviations of the magnetic needle
at any given station, which may be expected as the mean
result of the heating and cooling of the atmosphere for a given
season and hour, I find such a general accordance with the
results of observations, especially in the direction and generally
in the amount for ditFerent seasons of the decimation varia-
tion, as to give me the strongest hopes that I have assigned
the true physical cause of those variations, and shown the
inodus (rpertnidi of their production.
And now, my dear de la Eive, I must leave you and run
to othei- matters. As soon as I can send you a cofiy of the
papers I will do so, and can only say I hope that they will
meet with your approbation. With the kindest remembrances
to your son.
Believe me to be, my dear friend, ever truly yours,
M. Fakaday.
This hope of explaining the variations of terrestrial
magnetism by the magnetic properties of the oxj^gen
of the air was destined to be iUusor}^ At that time
the cosmical nature of magnetic storms was unknown
and unsuspected. To this matter we may well apj^ly
Faraday's own words addressed to Tyndall respecting
the alleged diamagnetic polarity, and the conflict of
views between himself on the one hand and Weber
and Tyndall on the other: — '' It is not wonderful that
views ditl'er at first. Time Avill gradually sift and
shape them. And I believe that we have little idea
at present of the importance they may have ten or
twenty years hence."
In 1851, from July to December, Faraday was
actively at work in the laboratory. The results
LINES OF MAGNETIC FORCE. 211
constitute the material for the twenty-eighth and
twenty-ninth (the last) series of the "Experimental
Researches." In these he returned to the subject
with which the first series had opened in 1831 : the
induction of electric currents by the relative motion
of magnets and conducting wires. These two
memoirs, together with his Royal Institution lecture
of January, 1852, " On the Lines of Magnetic Force,"
and the paper '* On the Physical Character of the
Lines of Magnetic Force" (which he sent to the
Philoso'phical Magazine, as containing " so much of
a speculative and hypothetical nature "), should be
read, and re-read, and read again, by every student
of physics. They are reprinted at the end of the
third volume of the " Experimental Researches."
In the opening of the twenty-eighth memoir he
says : —
From my earliest experiments on the relation of electricity
and magnetism, I have had to think and speak of lines of
magnetic force as representations of the magnetic power — not
merely in the points of quality and direction, but also in
quantity. . . . The direction of these lines about and
amongst magnets and electric currents is easily represented
and understood in a general manner by the ordinary use of
iron filings.
A point equally important to the definition of these lines
is, that they represent a determinate and unchanging amount
of force. Though, therefore, their forms, as they exist between
two or more centres or sources of power, may vary very
greatly, and also the space through which they may be traced,
yet the sum of power contained in any one section of a given
portion of the lines is exactly equal to the sum of power in
any other section "" of the same lines, ho weaver altered in form
['" This is exactly Stokes's theorem of '* tubes " of force. S. P. T,]
212 MICHAEL FARADAY.
or however convergeut or divergent they may be at the yeccucl
place. . . , Now, it appears to me that these lines may
be employed with great advantage to represent the nature,
condition, and comparative amount of the magnetic forces,
and that in many cases they have, to the physical reasoner, at
least, a superiority over that method Avhich represents the
forces as concentrated in centres of action, such as the poles of
magnets or needles ; or some other methods, as, for instance,
that which considers north or south magnetisms as fluids
diffused over the end, or amongst the particles, of a bar. No
doubt any of these methods which does not assume too much
will, with a faithful application, give true results. And so
they all ought to give the same results, as far as they can
resjiectively be applied. But some may, by their very nature,
be applicable to a far greater extent, and give far more varied
results, than others. For, just as either geometry or analysis
may be emjiloyed to solve correctly a particular problem,
thoui^h one has far more power and capability, generally
speaking, than the other; or, just as either the idea of the
reflexion of images or that of the reverberation of sounds may
be used to represent certain physical forces and conditions, so
may the idea of the attractions and repulsions of centres, or
that of the disposition of magnetic fluids, or that of lines of
force, be applied in the consideration of magnetic phenomena.
It is the occasional and more frequent use of the latter which
I at present wish to advocate. . . . When the natural
truth, and the conventional representation of it, most closely
agree, then are Ave most advanced in our knowledge. The
emission and aether theories present sucli cases in relation to
light. The idea of a fluid or of two fluids is the same for
electricity; and there the further idea of a current has been
raised, which, indeed, has such hold on the mind as occasion-
ally to embarrass the science as respects the true character of
the physical agencies, and may be doing so even now to a
degree which we at present little sus]iect. The same is the
case with the idea of a magnetic tiuid or fluids, or with the
assumption of magnetic centres of action of which the
resultants are at the poles.
'i'liE FU^^CT10N■S Ot' THi^ .KTHt^U. 'll'i
How the magnetic force is transferred through bodies or
through space we know not — -whether tlie result is merely
action at a distance, as in the case ot gravity, or by some
intermediate agency, as in the cases of light, heat, the electric
current, and, as I believe, static electric action. The idea of
magnetic fluids, as applied by some, or of magnetic centres of ^
action, does not include that of the latter kind of transmission, ''
but the idea of lines of force does. Nevertheless, because a
particular method of representing the forces does not include
such a mode of transmission, the latter is not disproved, and
that method of representation which harmonises with it may
be the most true to nature. The general conclusion of
philosophers seems to be that such cases are by far the most
numerous. And for my own part, considering the relation of
a vacuum to the magnetic force, and the general character of
magnetic phenomena external to the magnet, I am more
inclined to the notion that in the transmission of the force
there is such an action, external to the magnet, than that the
effects are merely attraction and repulsion at a distance.
>SWA an action may he a ftinction of the f.ethei\for it is not at
all unlikely that if there he an cethe7\ it should have other uses
than simply the conveyance of radiations/'
He then proceeds to recount the experimental
evidence of revolving magnets and loops of wire.
Following out the old lines of so moving the parts of
the system that the magnetic lines were " cut " by the
copper conductors, and connecting the latter with a
slow-period galvanometer, to test the resultant in-
duction, he found that " the amount of magnetic
force" [or fi'ux, as we should nowadays call it] "is
determinate for the same lines of force, whatever the
distance of the point or plane at which their power is
exerted is from the magnet." The convergence or
divergence of the lines of force caused, jyer se, no
[^ Tlie italics are mino. S. P. T.]
214 MICHAEL FARADAY.
difference in their amount. Obliquit}^ of intersection
caused no difference, provided the same Hues of force
were cut. If a wire was moving in a field of equal
intensity, and Avith a uniform motion, then the
current produced was proportional to the velocit)'" ot
motion. The " quantity of electricity thrown into
a current" was, ceteris 2^^?^^^^^-'', "directly as the
amount of curves intersected." Within the magnet,
I'unning through its substance, existed lines of force
of the same nature as those without, exactly equal in
ainount to those without, and were, indeed, con-
tinuotts with them. The conclusion must logically
be that every line of force is a closed circuit.
Having thus established the exact quantitative
laws of magneto-electric induction, he then advanced
to make use of the induced current as a means of
investigating the presence, direction, and amount of
magnetic forces — in other words, to explore and
measure magnetic fields. He constructed revolving
rectangles and rings furnished with a shnple commu-
tator, to measure inductively the magnetic forces of
the earth. Then he employed the induced current to
test the constancy of magnets Avhen placed near to
other magnets in ways that might affect their power.
Next he considers the fields of magnetic force of two
or more associated magnets, and notes how their
magnetic lines may coalesce when they are so placed
as to constitute parts of a common magnetic circuit.
The twenty-ninth series is brought to a close by a
discussion of the experimental way of delineating
lines of magnetic force by means of iron filings.
The paper on the " Physical Character of the
THE ELECTROTONIC STATE, 215
Lines of Magnetic Force " recapitulated the points
established in the twenty-ninth series of " Researches,"
and emphasis is laid upon the logical necessity that
time must be required for their propagation. The
physical effects in a magnetic field, as equivalent to a
tendency for the magnetic lines to shorten themselves,
and to repel one another laterally, are considered, and
are contrasted with the effects of parallel electric
currents. Commenting on the mutual relation
between the directions of an electric current and of
its surrounding magnetic lines, he raises the question
whether or not they consist in a state of tension of
the rether. " Again and again," he says, " the idea of
an electrotonic state has been forced on my mind.
Such a state would coincide and become identified
with that which would then constitute the physical
lines of mametic force." Then he traces out the
o
analogy between a maj^net, with its " sphondyloid "
(or spindle-form field) of magnetic lines, and a voltaic
battery immersed in water, with its re-entrant lines
of flow of circulating current. Incidentally, while
discussing the principle of the magnetic circuit, he
points out that when a magnet is furnished at its
poles with masses of soft iron, it can both receive and
retain a higher magnetic charge than it does without
them, " for these masses carry on the physical lines of
force, and deliver them to a body of surrounding
space, which is either widened, and therefore in-
creased, in the direction across the lines of force,
or shortened in that direction parallel to them, or
both ; and both are circumstances which facilitate
the conduction from pole to pole."
216 illCHAEL FARADAY.
Thus closed, with the exception of two fragmentaiy
papers, one on " Physical Lines of Force," and tlic
olher on "Some Points in Magnetic Philosophy," in
the years LS53 and LS54. respectively, the main lile-
Avork of Faraday, his " Fxperiniental Researches."
Their effect in revokitionising electric science, if slow,
was yet sure. Though the principle of the dynamo
was discovered and published in 1831, nearly forty
years elapsed before electric-lighting machinery
became a commercial product. Though the depend-
ence of inductive actions, both electromagnetic and
electrostatic, upon the properties of the intervening
medium was demonstrated and elaborated in these
" Researches," electricians for many years continued
to propound theories whicli ignored this fundamental
fact. French and German writers continued to
publish treatises based on the ancient doctrines of
action at a distance, and of imaginary electric and
]nagnetic iiuids. Yon Eoltzn:iann, a typical German
of the first rank in science, says that until there came
straioht from Eno^land the counter-doctrines amidst
which Farada}^ had lived, ''we (in Germany and
France) had all more or less iinbibed with our
mothers' milk the ideas of magnetic and electric
fluids acting direct at a distance." And again, "The
theory of Maxwell" — that is, Faraday's theory thrown
by Maxwell into mathematical shape — " is so dia-
metrically opposed to the ideas which have become
customary to us, that we must first cast behind us all
our previous views of the nature and operation of
electric forces before we can enter into its portals."
The divergence of view between Faraday and the
NOVELTY OF FARADAY'S VIEWS. 217
Continental electricians is nowhere move clearly
stated than by Faraday's great interpreter, Maxwell,
in the apolof/ia which he prefixed in 1873 to his
'' Treatise on Electricity and Magnetism," wdierein,
speaking of the diiferenccs between this work and
those recently pubHslied in Germany, he wrote: —
One reason of this is that before I began the stud}^ of
electiicity I resolved to read no mathematics on the subject till
I had fiist read through Faraday's "Experimental Hesearches
on Electricity." I was aware that there was ,su})])Osed to l)e
a difference between Faraday's way of conceiving i»henoniena
and that of the mathematicians. So that neither lie nor they
Avere satisfied with each other's language. I had also the
conviction that this discre]jancy did not arise from either
jiarty being wrong. I was lirst convinced of this by Sir
William Thomson [Lord Kehdn], to whose advice and assist-
ance, as Avell as to his i)ublished papers, I owe most of what
I have learned on this subject.
As I proceeded with the study of Faraday, I perceived
that his method of conceiving the phenomena was also a
mathematical one, though not exhiVjited in the conventional
furm of mathematical symbols. I also found that these
methods were capable of being expressed in the ordinary
mathematical forms, and thus compared with those of the
professed mathematicians.
For instance, Fiiraday, in Ids mind's 'eye, saw lines of
force traversing all space where the mathematicians saw
centres of foi-ce attracting at a distance. Faraday saw a
medium where they saw nothing but distance. Faraday
sought the seat of the phenomena in real actions going on in
the medium ; they were satisfied that they had found it in a
power of action at a distance impressed on electric fluids.
When I had translated what I considered to be Faraday's
ideas into a mathematical form, I found that in general the
rosnits of the two methods coincided, so that the same
phenomena were accounted for and the same laws of action
218 MICHAEL FARADAY.
deduced by both methods, but that Faraday's methods
resembled those in which we heiiiu witl) the wlioh* and arrive
at the parts by analysis, while the ordinary mathematical
methods were founded on the principle of beginnini;- with
the parts and building ui* the whole by synthesis.
I found, also, that several of the most fertile metliods of
research discovered by the mathematicians could be ex])rcsscd
much better in terms of ideas derived from Faraday than in
their ori,i;inal form.
The whole theory, for instance, of ])0tential, considered as
a quantity which satisfies a certain jtartial differential equation,
belongs essentially to the method which I liave called of
Faraday. . . .
If by anything I have here written I may assist any
student in understanding Faraday's modes of thought and
expression, I shall regard it as the accomplishment of one of
my principal aims ; to conuiuinicate to others the same delight
which I have found myself in reading Faraday's " llesearches."
Clerk Maxwell may also be credited with the
remark that Faraday's work had harl the result of
banishing the term " the electric fluid " into the
limbo of newspaper science.
Faraday's work for Trinity, House continued
during these last years of research work. He
reported on such subjects as adulteration of white
lead, impure oils, Chance's lenses, lighthouse ventila-
tion, and fog signals. Two systems of electric arc
lighting for lighthouses — one by Watson, ushig
batteries, the other by Holmes, using a magneto-
electric machine — were examined in 1S58 and 1854,
but his report on them was adverse. He " could not
put up in a lighthouse what has not been established
beforehand, and is only experimental" In 185G he
made five reports, in 1857 six, and in 1858 twelve
ELECTRIC LIGHT IN LIGHTHOUSES. 219
reports to Trinit}^ House, one of these being on the
electric hght at the South Foreland. In 1859 he
reported on farther trials in which Duboscq's lamps
were used. In 1860 he gave a final report on the
practicability and utility of magneto-electric lighting,
and expressed the hope it would be applied, as there
was now no diflSculty. In 1861 he inspected the
machinery as established at the Dungeness light-
house. In 1862 he gave no fewer than seventeen
reports, visiting Dungeness, Grisnez, and the South
Foreland, In 1863 he again visited Dungeness. In
1864 he made twelve reports, and examined the
drawings and estimates for establishing the electric
light at Portland. His last report was in 1865, upon
the St. Bees' light, and he then retired from this
service.
His Friday night discourses were still continued
during these years. In 1855 he gave one on
" Ruhmkorff's Induction-coil." In 1856 he gave one
on a process for silvering glass, and on finely
divided gold. This latter subject, the optical
properties of precipitated gold, formed the topic of
the Bakerian lecture of that year — his last contribu-
tion to the Royal Society. He gave another dis-
course on the same subject in 1857, and also one on
the conservation of force. In 1856, when investi-
gating the crystallisation of water, he discovered
the phenomenon of regelation of ice. In virtue of
this property two pieces of ice will fi'eeze solidly
together under pressure, even when the temperature
of the surrounding atmosphere is above the freezing
point. This discovery led on the one hand to the
220 MICHAEL FAKAJiAV.
explanation of glacier motions ; on the other to im-
portant results in thermodynamic theor}'. hi 1859
he gave two disconrses, one on ozone, the other
on phosphorescence and iinorescence. He also gave
two in ISiiO, on lighthouse illumination by electric
light, and on the electric silk-loom. In 18G1 he dis-
conrsed on platinum and on Do la Rue's eclipse pho-
tographs. The last of his Friday night discourses was
given on June 20th, 1N62. It was on Siemens's gas
furnaces. He had been down at Swansea watching
the furnaces in operation, and now proposed to
describe their principle. It was rather a sad occasion,
for it was but too evident that his powers were fast
waning. Early in the evening he had the misfortune
to burn the notes he had prepared, and becauje
confused. He concluded Avith a touching personal
explanation how with adA^ancing yeai's his memory
had failed, and that in justice to others he felt it his
duty to retire.
At inter-vals he still attempted to Avorlv at research.
In 1860 he sent a paper to the Royal Society on the
relations of electricity to gravity, but, on the
advice of Professor (afterwards Sir George) Stokes, it
Avas AvithdraAvn. He had also in contemplation some
experiments upon the time required in the propaga-
tion of magnetism, and beo'an the construction of a
complicated instrument, Avhich Avas never finished.
His A^ery last experiment, as recorded in his labora-
tory notebook, is of extraordinary interest, as shoAving
liOAv his mind Avas still at Avork inquiring into the
borderland of possible phenomena. Jt Avas on March
12lh, 18G2. He Avas inquiring into the effect of a
HYPOTHESIS AND EXPERIMENT. 221
magnetic field upon a beam of light, which he was
observing with a spectroscope to ascertain whether
there was any change produced in the refrangibility
of the hght. The entry conchides : " Not the shghtest
effect on the polarised or unpolarised ray was ob-
served." The experiment is of the highest interest
in magneto-optics. The effect for which Faraday
looked in vain in 18G2 was discovered in 1.S97 by
Zeeman. That Faraday should have conceived the
existence of this obscure relation between magnetism
and light is a striking illustration of the acuteness of
mental vision which he brought to bear. Living and
working amongst the appliances of his laboratory,
letting his thoughts play freely around the pheno-
mena, incessantly framing hypotheses to account for
the facts, and as incessantly testing his hypotheses by
the touchstone of experiment, never hesitating to
push to their logical conclusion the ideas suggested
by experiment, hoAvever widely they might seem to
lead from the accepted modes of thought, he worked
on with a scientihc prevision little short of miraculous.
His experiments, even those which at the time
seemed unsuccessful, in that they yielded no positive
result, have proved to be a mine of amazing richness.
The volumes of his "Experimental Piesearches" are a
veritable treasure-house of science.
CHAPTER VI.
MIDDLE AND LATER LIFE.
Although to avoid discontinuity the account of
FaTada3''s researches has in the previous chapter been
followed to their close in 1862, we must now return
to his middle period of life, when his activities at the
Royal Institution were at their zenith.
Mention has been made of the serious breakdown
of Faraday's health at the close of 1889. Dr. Latham,
whom he consulted as to his attacks of giddiness,
Avrote to Brande : —
Orosvenor Street,
December 1, 1831).
Dear I^randk,— I have been seeing onr friend Faraday
these two or three days, and been looking after his liealth. I
trust he has no aihnent more than rest of body and mind will
get rid of. But rest is absolutely necessary for him. Indeed,
I think it would be hardly prudent for him to lecture again
for the present. He looks uj* to his work ; but, in truth, he
is not fit, and if he is in^essed he will suddenly break down.
When we meet, I will talk the matter over with you.
Yours most sincerely,
P. M. Latham.
The advice was taken. He gave up nearly all
research Avork, but tried to go on with Friday night
BREAKDOWN OF HEALTH. 223
discourses and afternoon lectures in 1 8 40. Then
came a more serious breakdown, and he rested for
nearly four years, with the exception of the Christmas
lectures in 1841 and a feAV Friday discourses in 1842
and 1843. This illness caused him great distress of
mind, mainly due to an idea that the physicians did
not understand his condition. When in this state he
sometimes set down pencil notes on scraps of paper
to relieve his feelings. One such is the following:—
Whereas, according to the declaration of that true man of
the world Talleyrnnd, the use of language is to conceal the
thoughts ; this is to declare in the present instance, Avhen I
say lam not able to bear much talking, it means really, and
without any mistake, or equivocation, or oblique meaning, or
implication, or subterfuge, or omission, that I am not able ;
being at present rather weak in the head, and able to work
no more.
During these times of enforced idleness he used
to amuse himself with games of skill, with paper-
work, and with visits to the theatre and to the
Zoological Gardens. Mrs. Faraday left the following
note : —
Michael was one of the- earliest members of the Zoological
Society, and the Gardens were a great resource to him when
overwrouglit and distressed in the head. The animals were a
continual source of interest, and Ave, or rather I, used to talk
of the time when we should be able to afford a house M'ithin
my Avalking distance of the entrance ; for I much feared he
could not continue to live in the Institution with the continual
calls upon his time and thought ; but he always shrank from
the notion of living away from the R. I.
His niece, Miss Reid, told how fond he was of
seeing acrobats, tumblers, dwarfs and giants; even
224 MICHAEL FARADAY.
a Punch and Jiicl}^ show was an unfailing source of
deUght, When travelhug in Switzerhxnd, as he did
on several occasions, accompanied by Mrs. Faraday
and her brother, George Barnard, the artist, he kept
a journal, which reveals his simple pleasures and
enthusiasms. He is delighted with waterfalls and
avalanches, watches the cowherd collecting his cows
and the shepherd calling the sheep, which followed
him, leaving the goats to straggle. On one such
visit (in 1S41), in order that he might not be absent
on Sunday from his wife, he Avalked the whole
distance from Leukerbad to Thun, over the Gemmi —
a distance of 45 miles — in one day. At Interlaken,
observing that clout-nail-making was practised as a
local industr3^ he wrote : " I love a smith's shop and
everything relating to smithery. My father Avas a
smith."
In 1844 he was well enough to attend the British
Association meeting at York. Liebig, who had also
been there, wrote to him three months later with
some reminiscences. What had struck him most
Avas the tendency in England to ignore the more
purely scientitic Avorks and to value only those with
a "practical" bearing. "In Germany it is quite the
contrary. Here, m the eyes of scientific men, no
value, or at least but a trifling one, is placed on the
practical results. The enrichment of science is alone
considere<l Avorthy of attention." Liebig further ex-
pressed himself dissatisfied Avith the meeting at York.
He had been iiiterested to make the acquaintance of
so many celebrated men, but it Avas, strictly, "a feast
given to the geologists, the other sciences serving only
ntPHEssiOXS OF LIEBIG. 225
to dec-orate the table." Then came a more personal
note : —
Often do my thougliti^ wander back to the period which I
spent in England, among the many pleasant hours of which
the remembrance of those passed with you and your amiable
wife is to me always the dearest and most agreeable. With
the purest pleasure I bring to mind my walk Avith her, in the
botanical garden at York, when I w.ts affoided a glance of the
richness of her mind ; what a rare treasure you i:to>?e>s in
her! The breakfast in the little hou^e with Snow Harri>,
and Graham, and our being together a-t Bi>hupthorpe, are :^till
fresh in my memory.
It" Liebig was disposed to underrate the useful
apphcations of science, Faradav certainly was not.
Though his own research work was carried on with
the single aim of scientihc progTess : though he him-
self never swerved aside into any branch research that
might have }-ielded money: yet he was ever ready to
examine, and even to lecture upon, the inventions of
others. He accepted for the subjects of his Friday
night discourses all sorts of topics — artiticial stone,
machinery for pen-making, lithogTaphy, Piuhmkortf's
induction coil, a process for silvering mh-rors, and
lighthouse illmnination by electric light. His very
last lecture was on Siemens's gas-furnaces. He could
be just as enthusiastic over the invention of another
as over some discovery of his own. AYith respect to
his lecture on the EuhmkorH' coil, T3-ndall describes
him in a passage which is interestino;, as containino- an
epithet smce adopted for another great man for whom
Tyndall had less respect than for Faradav : —
p
•226 MICHAEL FARADAV.
I Avell vemeaibei' tlie ccst;isy and sur[iri.sc ct' the (frmul uhl
mill, evoked by effect,^ which we should now deem utterly
iijsiguitieant.
Bence Jones says : —
AVheu he brought the discoveries of others before hi:,
hearers, one object, and one ahme, seemed to determine all
lie said and did, and that was, " without commendation and
without censure," to do the utmost that could be cione for the
discoverer.
In so perfect a charactei' it would be marvellous if
there were not some flaw. His persistent ignoring of
Sturgeon, and his attribution of the invention of the
electromagnet to Moll and Henry, whose work "vvas
frankly based on Sturgeon's, is simply inexplicable.
He failed to appreciate the greatness of Dalton, and
thought him an overrated man.
Amid all his overflowing kindliness of heart,
Faraday preserved other less obvious traits of char-
acter. Any act of injustice or meanness called forth
an almost volcanic burst of indignation. Hot flashes
of temper, tierce moments of wrath were by no means
unknown. But he exercised a most admirable self-
control, and a habitual discipline of soul that kept his
temper under. Grim and forbidding, and even exact-
ing he could show himself to an idle or unfaithful
servant. There were those who feared as well as
those who loved and admired him. Dr. Gladstone
says of him that he was no " model of all the virtues, '
dreadfully uninteresting, and discouraging to those
who feel calm perfection out of their reach. "His
inner life was a battle, with its wounds as well as its
PERSONAL CPlAltACTERlSTlCS. 227
victory." "It is true also," he adds, " that with his
great caution and his repugnance to moral evil, he
was more disposed to turn away in disgust from an
erring companion than to endeavour to reclaim him."
For thirty 3^ears Faraday was the f oren lost of
lecturers on science in London. From the tirst
occasion Avhen, in 1JS23, as Sir Roderick Murchison
narrates, he was called upon unexpectedly to act as
substitute for Professor Brande at one of his morning
lectures at the Royal Institution (then held in the
subterranean laboratory), down to the time of his
latest appearance as a lecturer in lS(j2, he was
without a rival as the exponent of natural science.
As no man could achieve and retain such a
position without possessing both natural gifts and
appropriate training, it is fitting to inquire what were
those gifts and what the training which "vvere so
happily united in hinr.
I was (he said) a very livel}^, imaginative person, and could
believe in the Arabian Nights as easily as in the Encyclopaedia ;
but facts were iinpuvtant to me, and saved me. I could trust
a fact, and always cross-examined an assertion.
From the very £rst Faraday had an appreciation
of the way in which public lectures should be given.
In his notes of Davy's fourth lecture of April, 1812,
he wrote : —
During the whole of these observations his delivery was
easy, his diction elegant, his tone good, and his sentiments
sublime.
His own first lecture was given in the kitchen of
Abbott's house, with home-made appai-atus placed on
228 MICHAEL FARADAY.
the kitchen table. To Abbott, after only a few weeks
of experience at the Royal Institution, he wrote the
letters upon lectures and lecturers, to which allusion
was made on p. 15. These show a most remark-
ably sound perception of the material and mental
furniture requisite for success. From the third and
fourth of them are culled the foIloAving excerpts : —
The most prominent requisite to a lecturer, though perhaps
not really the most important, is a good delivery ; for though
to all true philosophers science and nature will have charms
innumerable in every dress, yet I ani sorry to say that the
generality of mankind cannot accompany us one short hour
unless the path is strewed with Howers. In order, therefore,
to gain the attention of an audience (and what can be more
-disagreeable to a lecturer than the want of it?), it is necessary
to jtay sojne attention to the manner of expression. The
utterance should not be rapid and hurried, and consequently
unintelligible, but slow and deliberate, conveying ideas with
ease from the lecturer, and infusing them with clearness and
readiness into the minds of the audience. A lecturer should
endeavour by all means to obtain a facility of utterance, and
the power of clothing his thoughts and ideas in language
smooth and harmonious, and at the same time simple and easy.
With respect to the action of the lecturer, it is requisite
that he should have some, though it does not here bear the
importance that it does in other branches of oratory ; for
though I know of no species of delivery (divinity excepted)
that requires less motion, yet I would Ity no means have a
lecturer glued to the table or screwed on the floor. He must
by all means appear as a body distinct and separate from the
things aroimd him, and must have sonie motion apart from
that which they possess.
A lecturer should appear easy and collected, undaunted
and unconcerned, his thoughts about him, and his mind clear
and free for the contemplation and description of his subject.
His action should not be hasty and violent, but slow, easy, and
QUALIFICATIONS OF A LECTUUEII. 229
niitura], con.sisting principally in changes of the posture of the
liDily, ill urdor to avoid the air of .stitfness or sameness that
Avriuld otherAvise be unavoidable. His whole behaviour should
evince respect for his audience, and he should in no case
forget tha.t he is in their jiresence. No accident that does n(.)t
interfere Avitli their convenience should disturb his serenity, or
cause variation in his behaviour ; he should never, if possible,
turn his back on them, but should give them full reason to
believe that all his ])Owers have been exeited for their pleasure
and instruction.
Some lecturers choose to express tlieir thoughts extempora-
neously immediately as they occur to the mind, whilst others
previously arrange them and draw them forth on paper. But
although I alh:)w a lecturer to Avrite out his matter, I do not
approve of his reading it— at least, not as he would a quotation
or extract.
A lecturer should exert his utmost effort to gain comjiletely
the mind and attention of his audience, and irresistibly to
make them join in his ideas to the end of the subject. He
should endeavour to raise their interest at the commencement
of the lecture, and liy a series of imperceptible gradations,
umioticed by the company, keep it alive as long as the subject
demands it. A Hame should be lighted at the commencement,
and kept alive with unremitting splendour to the end. For
this reason I very much disapprove of breaks in a lecture, and
where they can by any means be avoided they should on no
account find place. . . . For the same reason— namely,
that the audience should not grow tired — I disapprove of long
lectures ; one hour is long enough for anyone. Nor should
they be allowed to exceed that time.
A lecturer falls deeply beneath the dignity of his character
when he descends so low as to angle for claps and asks for
commendation. Yet have I seen a lecturer even at this point.
I have lieard him causelessly condemn his own powers. I
have heard him dAvell for a length of time on the extreme care
and niceness that the exfieriment he will make requires. I
have heard Lim ho]ie for indulgence when no indulgence was
wanted, and I have even heard him declare that the experi-
230 MICHAEL FARADAY.
inent now made cannot fail, from its l>caiity, its correctness,
and its application, to gain the approbation of all. ... 1
would wish apologies to be made as seldom as possible, and
generally only Avhen the inconvenience extends to the
com])any. I have several times seen the attention of by far
the greater ])art of the audience called to an error l>y the
apology that followed it.
'Tis w^ell, too, Avhen the lecturer has the ready wit and the
])resence of mind to turn any casual circumstance to an illus-
tration of his subject. Any ]tarticu]ar circnmstauce that has
become table-talk for the town, any local advantages or dis-
advantages, any trivial circumstance that may arise in com-
liany, give great force to illustrations ajitly drawn from them,
and ])lease the audience highly, as they conceive they i)erfectly
understand them.
Apt experiments (to Avhich I have liefore referred) ought to
be explained by satisfactory theory, or otherwise Ave merely
])atch an old coat vi'ith new cloth, and the whole [hole] becomes
Avorse. If a satisfactory theory can be given, it ought to be
given. If we doubt a received opinion, let us not leave the
doubt unnoticed and affirm our own ideas, but state it clearly,
and lay down also onr objections. If the scientific world is
divided in opinion, state both sides of the question, and let
each one judge for himself hy noticing the most striking and
forcible circumstances on each side. Then, and then only,
shall we do justice to the subject, please the audience, and
satisfy our honour, the honour of a i)hilosoplier.
One wdio already had set before himself such bi^h
ideals could not fail at least to attempt to fulfil them.
Accordmgly, when in ISIG he began to lecture to the
City Philosophical Society, he Leoan to attend an
evening class on elocution conducted by Mr. B. H.
Smart, though the pinch of poverty made it difficult
to him to afford the needful fees. Again, in 1823,
previous to taking part in Brando's laborator}^ lectures,
USE OF CRITICISM. 231
he took private lessons in elocution from Smart, at
the rate of half-a-guinea a lesson. After 1827, when
he was beginning his regular courses of lectures in the
theatre, he often used to get Mr. Smart to attend in
order to criticise his delivery.
Amongst the rules found in his manuscript notes
were the following : —
Never to repeat a phrase.
Never to go back to amend.
If at a loss for a word, not to ch-cli-cli or eh-eh-eh, Imt to
stop and wait for it. It soon comes, and the bad habits are
broken and fluency soon acquired.
Never doubt a correction given to me by another.
His niece, Miss Rcid, who lived from 1830 to 1840
at the Institution with the Faradays, gave the following
amongst her recollections : —
^[r. Magrath used to come regularly to the morning lec-
tures, for the sole purpose of noting down for him any faults
of delivery or defective pronunciation that could be detected.
The list was always received with thanks ; although his cor-
rections were not uniformly adopted, he Avas encouraged to
continue his remarks with perfect freedom. In early days he
always lectured with a card before liim with SUno Avritten upon
it in distinct characters. Sometimes he would overlook it and
become too rapid ; in this case, Anderson had orders to ])lace
the card before him. Sometimes he had the word Time on a
card brought forward when the hour was nearly exjjired.
In spite of his recourse to aids in acquiring elocu-
tionary excellence, his own style remained simple
and unspoiled. " His manner," says Bence Jones,
" Avas so natural, that the thought of any art in his
lecturing never occurred to anyone. For his Friday
232 MICHAEL FAltADAY.
discourses, and for his other set lectures in tlie tlieatre,
he always made ample preparation beforehand. His
matter Avas always over-abundant. And, if his ex-
periments were always successful, this was not solely
attributable to his exceeding skill of hand. Ynr, un-
rivalled as he was ns a manipulator, in the cases in
which he attempted to shoAv complicated or ditHcult
experiments, that which was to be shown Avas always
well rehearsed beforehand in the laboratory. He was
exceedingly particular about small and simple illus-
trations. He never merely told his hearers about an
experiment, but showed it to them, however simple
and well known it might be. To a young lecturer he
once remarked ; ' If I said to my audience, "This stone
will fall to the ground if I open my hand," I should
open my hand and let it fall. Take nothing for granted
as known; inform the eye at the same time as you
address the ear.' He always endeavoured at the
outset to put himself en ra/p2')ort with his audience by
introducing his subject on its most familiar side, and
then leading on to that which Avas less familiar. Jjefore
the audience became aAvare of any transition, they
Arerc already assimilating ncAv facts Avhich Avere thus
brought Avithin their range. Nor did he stay his dis-
ct)urse upon the enunciation <»f facts merely. Alnjost
invariably, as his allotted hour drcAv toAvards its close,
he gave I'ein t(.t his imagination. Those Avdio had
Ijegun Avith him on the loAver plane of simple facts
and their correlations Avere bidden to consider the Avider
bearings of scientitic principles and their relations to
philosoph}', to life, or to ethics, ^^■hile he never
^nvvQf] a perriration, nor draggof] i^ a (piotation from
A,S LKCTIJltEJI. Zoo
the poets, his own scientific inspiratitjn, as he outlined
some Avirle-sweeping' speculation or suggestion for
future discoveries, amply supplied the Htting iinale.
If the rush of his ideas might sometimes be compared
to tearing through a jungle, it at least never degen-
erated into sermonisinir ; and never, save "vvhen he
■was physically ill, failed to arouse an enthusiastic glow
of response in his hearers. ' No attentive listener,'
says Mrs. Crosse, 'ever came away from one of Fara-
day's lectures wuthout having the limits of his spiritual
vision enlarged, or without feeling that his imagination
had been stimulated to something beyond the mere
expression of physical facts.' "
He was not one who let himself dwell in illusions.
When he did Avell he was perfectly conscious of the
fact, and enjoyed a modest satisfaction. If he had
failed of his best, he was conscious too of that. His
deliberate act in giving up all other lectures at the
time when his brain-troubles were gaining upon him,
while retaining the Christmas lectures to juveniles,
was thoroughly characteristic. Of one of his earlier
courses of lectures he himself made — about 1(S32 —
the following note : —
The eight lectures on the operations of the laboratory at
the Koyal Institution, April, T828, wtre not to uiy minrl.
There does not appear to be that opportunity of fixing the
attention of the audience by a single clear, consistent, and
connected chain of reasoning which occurs when a principle
(sic) or one particular application is made. . . . I do not
think the operations of the laboratory can be rendered useful
and popular in lectures. . . .
The matter of these same lectures was, however,
the basis of his book on Chemical Manipulation
2;i4 MICHAEL FARADAV.
published in 1827. It went througli three editions,
and was reprinted in America. But in 1838 he
decHned to let a new edition be issued, as he con-
sidered the work out of date.
Besides the note quoted above from the Faraday
MS. occurs the following : —
The six juvenile lectures given Christmas, 1827, were just
what they ought to have been, both in matter and manner;
but it would not answer to give an extended course in the
same spirit.
Nineteen times did Faraday give the Christmas
lectures. Those on the Chemistry of a Candle were
given more than once ; and were the last he gave, in
LSflO. They have been pul:)lished, as were those on
tbc Forces of Nature. The lectures on Metals he
was urged to publish, but declined in the following
terms : —
Pioyal Institution, January 3, 1850.
Dear Sir, — ^lany thanks to both you and Mr. Bentley.
jNIr. ilurray made me an unlimited offer like that of Mr.
Bentley's many years ago, but for the reasons I am aljout to
give you I had to refuse his kindness. He proposed to take
them by shorthand, and so save me trouble, but I kneAv that
would be a thorough failure ; even if I cared to give time to
the revision of the MS., still the lectures without the ex])eri-
ments and the vivacity of speaking wuuld fall far behind tho.^e
in the lecture-room as to effect. And then I do not desire to
give time to them, for money is no temptation to me. In fact,
I have always lovtd science more than money ; and because
my occupation is almost entirely personal I cannot alford to
get rich. Again thanking you and Mr. Bentley, I remain.
Very truly yours,
M. Faraday.
AX IXSPIRED CHILD. 235
Of his lectures Lady Pollock wrote : —
He would play Avith his suliject now and then, but very
delicately ; his sport was only ju.st enough to enliven the
attention. He never suffered an experiment to allure him
away from his theme. Every touch of his hand was a true
illustration of his argument. . . . But his meaning was
sometimes beyond the conception of those whom he addressed.
^yhen, however, he lectured to children he was careful to be
perfectly distinct, and never allowed his ideas to outrun their
intelligence. He took great delight in talking to them, and
easily won their confidence. The vivacity of his mnuner iind
of his countenance, and his pleasant laugh, the f)-ankness of his
whole bearing, attracted them to him. They felt as if he
belonged to them ; and indeed he sometimes, in his joyous
enthusiasm, a]tpeared like an inspired child.
. . . His quick sympathies put him so closely in relation
with the child that he saw with the boy's ncAv wonder, and
looked, and most likely felt for the moment, as if he had never
seen the thing before. Quick feelings, quick movement, quick
thought, vividness of exi)ression and of perception, belonged to
him. He came across you like a flash of light, and he seemed
to leave some of his light with you. His presence was always
stimulating. — St. PauFs Mugazine^ June, 1870.
A writer in the British Qiiarterljf Reviev) says : —
He had the art of making philoso])hy charming, and this
was due in no little measure to the fact that to grey-headed
wisdom he united wonderful juvenility of spirit. . . .
Hilariously boyish upon occasion he could be, and those wlio
knew him best knew he Avas never more at home, that he
never seemed so pleased, as when making an old boy of him-
self, as he wns wont to say, lecturing before a juvenile audience
at Christmas.
Caroline Fox (in " Memories of Old Friends "),
under date June 13th, 1851, wrote in her journal ; —
2'4{) :\ii(ii.\EL fai:ai).\v.
We Avent to Faraday's lerturu on "Ozone." He tried the
\ariuu.s methods of making ozone \vhich Schunbein liad already
lierformed in our kitchen, and he did them brilliarjtly. He
was entirely at his ease, botli witii his audience and his
rliemical ajiparatus.
In the diary of H. Crabb Robinson is an apjirecia-
ti'.tn of Faraday of some interest : —
May 8th, 1S40. . . . Attended Carlyles second lecture.
It gave great satisfaction, for it had uncommon thoughts and
was delivered with unusual animation. ... In the evening
heard a lecture by Faraday. What a contrast to Carlyle ! A
perfect exiieriatentalist with an intellect so clear. Within liis
sj)here ti7i nomo cnnipito.
Many references to Faraday's lectures occur in the
life of Sir Richard Owen ^published 1S04}, chiefly ex-
tracted from ]\[rs. Owen's diary. Two or three extracts
must suffice : —
]8:i!), -Ian. sth. At eight o'clock with It. to the iloyai
Institution to liear Faraday lecture on electricity, galvanism,
and the electric eel. Faraday i.s the Ix^aic ideal of a popular
lectui'er.
l>^4-"t, Jan. 3]. To Faraday's lecture at the Koyal Institu-
tion. The largest crowd I have ever seen there. Many
gentlemen were obliged to come into the ladies' gallery, as
they could not get seats elsewhere. After an exceedingly
interesting lecture, Farad;iy said he had a few remarks to
make on some new reform laws for the In.-^titution. These
remarks Avere admirably made, and no one could feel ofi'ended,
although it was a direct attack on those gentlemen who helped
to render the ladies very uncomfortable, sometimes hy filling
seats, and often front seats, in the part intended only for
ladies. Wearing a hat in the library was one of the delin-
quencies, likewise sitting in the seats reserved for the directors,
who were oblig-ed bv their office and duties to be last in. Mr.
ROYAL INSTITUTION LECTURES. 237
Faraday also remarked that the formation of two currents
caused by certain gentlemen rushing upstairs the instant the
lecture Avas over to fetch their lady friends Avas not conducive
to the comfort of those coming downstairs. Eve.rything taken
very well.
1849, May :>8th. AVith R. to lloyal Institution. AVe got
there just before three, and there was a crowded audience as
usual to hear Faraday's lecture. The poor man entered and
attem](ted to speak, but he was suffering from inflammation or
excessive irritation of the larynx, and after some painful efforts
to speak, a general cry arose of '* Postpone," and sotneone,
appaiently in authority, made a short speech from the gallery.
Mr. Faraday still wished to try and force his voice, saying he
was well aware of the difficulty of getting back the carriages,
etc., before the time for the lecture had elapsed, to say nothing
of the disappointment to some ; but every moment the cry
increased. *' No, no ; you are too valuable to be allowed to
injure yourself. Postpone, postpone." Poor Faraday was
(]uite overcome.
The interrupted lecture was resumed after a fort-
night's interval; and he made up the full number
of lectures Ly giving two extra discoiu'ses, at one (.)f
wliich the Prince Consort Avas present.
At another lecture [in 1856] Faraday explained the magnet
and strength of attraction. He made us all laugh heartily ;
and when he threw a coalscuttle full of coals, a poker, and a
pair of tongs at the great magnet, and they stuck there, the
theatre echoed with shouts of laughter.
His friend De la Rive testified in striking terms
to Faraday's power as a speaker.
Nothing can give a notion of the charm wliich he imparted
to these improvised lectures, in which he knew how to
combine animated, and often eloquent, language with a
judgment and art in his experiments which added t<.) the
'2SH MiCHAEr. FAUADAY.
clearness and elegance of his exposition. He exerted an
actual fascination upon his auditors ; and when, after having
initiated them into the mysteries of science, he terminated his
lecture, as he was in the habit of doing, hy rising into regions
far alcove matter, space, and time, the emotion which he
experienced did not fail to communicate itself to those who
listened to him, and their enthusiasm had no longer any
iKjunds.
FarafL\y remained all his life a keen observer of
other lecturers. Visiting France in 1845, he went
to licar Araf>:o i^ive an astronomical lecture. " He
delivered it in an admirable manner to a crowded
audience," was his connnent.
To the Secretary of the Institution, who in LS4G
consulted him regarding evening lectures, he said:
I see no objection to evening lectures if you can find a tit
man to give them. As to jjopular lectures (which at the same
time are to be fespectahlt^. and soiuid), none are more difficult
to find. Lectures which renlli/ teacii will never be popidar ;
lecturijs which are jjopular will never really teach. They
knt.iw little of the mattt-r who think science is more easily to
be taught or learned than A B C ; and yet who ever learned
his A E C without pain and trouble? >Still, lectures can
(generally) inform the mind, and show forth to the attentive
man what he really has to learn, and in their way are very
useful, esjjecially to the i)ublic. I think they might be useful
to us now, even if they only gave an answer to those who,
judgiijg by their own earnest desire to learn, think much of
them. As to agricultural chemistiy, it is no doubt an
excellent and a popular subject, but I rather suspect that
thosh; who know lea^t of it think thnt most is known about it.
His fondness lor illustrating obscure points in his
lectures Ijy models has been more than once alluded
to. He would improvise these out of wood, pa2Jer,
USE OF MitliELS AXI) CARDS.
2:in
Avire, or even out of turnips or potatoes, with much
dexterit}' of hand. In one of his iinpubhshed
manuscripts, dating about 1826, deahng with the
then recently discovered phenomena of electro-
magnetism, occurs the following note: —
It is best for illustration to have a innJel of the constant
li'isitinn which tlic iieeillc takes across the wire : le v<>i.la
(Fig. 1^1).
Man}' such simple models were used in his
lectures. He leaned upon them to aid his defecri\'e
memory; but they helped his audience quite as nuich
as they aided him. Reference was made on p. 7 to
his use of cards, on wdiich to jot down notes of
thoughts that occurred to him. One such runs as
follows ; —
Ren:ember to do one thing at once.
Also to finish a thing.
Also to do a little if I could not do iiiucJi.
Pique about mathematics in chemists, and resolution to
support the character of experiment — as better for the mass.
Hence origin of the title Exp. resenrchts.
Influence of authority. Davy and difficulty of steering
between self-siifflcltncy and dependance (.s/c) on ntliers.
240 MICHAEL KAIIADAV.
Aim ;it lii;j;li lliiii^^s, ln.it nuL iirL'siiiii|itiiinisly.
Endcav(.mr In .succeed -uxpLw.;t iioL tn sii(;(;(;e*l.
Cr/'firis/-' (Die's own view in every way ljy ex|ie)'iiiiriit.- if
po.s-iibic, leave iin i>l>jcelinii to l>e piil liy otiieis.
J^\ir;t(ljiy'.s ontlmsiiisiii ji!joii(, oxporinioiiljil re-
searches was at tinios iinrestraincrl, and always
contagions. Dnnias dcsci-iljos how Faraday repealed
for hini the ex})eriniental dcinonstj'ation of the action
of niaij^Jietisra on hght. Having corrie to the iinal
cxi)crinient, Faraday rubbed his hands excitedly,
while his eyes ht up with tire, and his animated
countenance told the passionate feelings whicli he
Ijrought to the discovery of scientitic truth. On
another occasion Plticker, of Borni, then <ni a visit to
London, showed Faraday in his own laboratory tlie
action (jf a magnet upon tlie ]urnin<jus elc(d.ric
discharge in vacuum tubes. "Faraday danced round
them; and as he saw the moving arclies of liglit, he
cried: ' Uh, to live always in it!'" Once a friend
met hini at Eastbourne in the midst of a tremendous
storm, rubbing his hands together gleefully Ijecause
lie had been fortunate enough to see the liglitniiig
strike tlie church tower. To the Ikironess Burdett-
Coutts he once wrote inviting her to see some
experiments upon spectrum analysis in his private
room. The experiments, he wrote, vriU not he
hea/tUiftd except to the iatelligeii/L
Yet another reminiscence is to be found in the
Memorials of Joseph Henry. It relates, probably, U>
the date of 18^7, when Henry visited Euro2Je.
FKEEiJOM OF SPECULATIOX. 24? L
Henrj' loved to dwell on the houris tliat he and Bache had
s^ient in h'aradays society. I shall never forget Henry's
account of his visit to King's College, London, where Faraday,
Wheatstone, Daniell, and he had met to try and evolve the
electric spark from the thermopile. Each in turn attempted
it and failed. Then came Henry's turn. He succeeded,
calling in the aid of his discovery of the efte(;t of a long
interpolar wire wrapped around a piece of soft iron. Faraday
became as wild as a boy, and, jumping np, shouted : " Hurrah
for the Yankee experiment ! "
The following inemoranduiii was found on a slip
of paper in Faraday's " research drawer " : —
THE FOITII DEGUEES.
The disc(>verer of a fact. y
The reconciling of it to known principles.
Discovery of a fact not reconcilable.
He wdio refers all to still more general jirinciples.
M. F.
Faraday's mind was of a very individnal turn; he
conld not walk along the beaten tracks, but must
pursue truth Avherever it led him. His dogged
tenacity for exact fact was accompanied by a perfect
fearlessness of speculation. He Avould throw over-
board without hesitation the most deeply-rooted
notions if experimental evidence pointed to newer
ideas. He had learned to doubt the idea of j^oles ; so
he outgrew the idea of atoms, Avhich he considered
an arbitrary conception. Many Avho heard his bold
speculations and his free coinage ot new terms
deemed him vague and loose in thought. Nothing
could be more untrue. He let his mind play freely
about the facts; he framed thousands of hypotheses,
242 mk;makl kahaimv.
only U> lot thciii go by if Uif^y wore not sijf>fK>rtod by
facts. "Ho is the wisest philoHf>j>bor," ho said in a
locture on the natnro of n)attor, "who holds \uh
theory with somo donbt> — who is ahio to [jroportion
his judgment and oonlidonoo U> tho valuo of tho
evidonoo sot hoforo liim, taking a fact for a fact and a
siippoKition for a Hnp[)OKitif>n, as Trmofi as possible
keeping his mind free irom all source of pn^jufliee;
or, where he cannot do tfiis (as in the ease of a
theory), romemhering tJjat such a source is there."
In one of his later experimental roKeareJios he
wrote : —
An an oxperirncntfiJiHt, J feel bound to let exp'-rirnent
^^uide rne into any train of thoijf<}»t whiclj it may justify ;
being Hiii'i'^iicA thai experiment, like analyHix, niuwt leiJ'l to
strict truth if rightly \uii:v\)V*-Xf'A -^ and believing jjIho that it
iH in itH nuime far njore suggeHiive of new trainH of thought
and new conditionn of natural power.
Perhaps it was this very freedrnn of tliooght
which debarred hirn from onh'sting other men as
collaborators in his reHoarcljos, IJi^ one assistant
for thirty years, Sergeant Anderson, was indeed in-
valuable to him for bis quality of implicit obcrlienee.
Other helpers in the lal^oratory he ha^l none. Ap-
parently he found hix researches to }>e of too indi-
vidual a eharaeter t/> pennit him t/j deputise; any part
of his work, lie wa« never satiwfiefl when told al>f»ut
another's experiment; he rniwt porforrrj it for hUumK,
Often a discovery arose from some chari';^^ or trivial
incident of an otharwim unsuccessful experiment.
The power oi ''kt^^al vision," which Tyndall has
so strongly emphasised, was a j;rimo factor in his
WHY XO SUCCESSOR. -43
successes. That power could not be delegated to any
uiere assistant. ^lany times did outsiders approach
him. thinking to bring new facts to his notice: never,
save on the solitary occasion when a Mr. William Jenkin
drew his attention to the "■ extra-current " spark seen
on the breaking of an electric circuit, did such novelties
turn out to be really new. Alleged discoveries thus
brought to him merely plagued him. He thought
that anyone who had the wit to observe anv really
new phenomenon woidd be the person best cpialitied
to work it out. His method was to work on alone,
dwelling amidst his experiuients until the mind,
familiarising itself Avith the facts, was ready to suggest
their correlations. It was sometimes urged against
him as a complaint that he never took up any younger
man to train him as his successor, even as Pavy had
taken up himself and trained him in scientitic work.
One of the miscellaneous nines, found after his death.
throws some liirht on this : —
o
'^ It puzzles me greatly to know what makes the successful
philosopher. Is it industry and perseverance with a moderate
proportion of good sense and intelligence? Is nut a modest
assurance or earnestness a requisite ' Do not many fnil be-
cause they look rather to tlic renown to be acquired than to
the i>ure acquisition of knowledge, and the delight which the
contented niind hns in acquiring it for its own sake? lam
sure I have seen many who would have been good and success
tul pursuers of science, and have gained themselves a high
name, but that it was the name and the reward they were
:dw;iy-^ looking forward to— the reward of the world's jiraise.
In ^uch there is always a shade of envy or regret over their
minds, and I cannot imagine a man making discoveries iu
science under these feelings. , As to Cieuius and its power,
244 MICHAEL FARADAY.
there iiiuy l>c cawcs ; I sii]i|)usc there are. 1 have looked lon.i;'
and often for a .renins for our Laboratory, but have never found
one. TUit I Jiave seen nmuy :vho would, I think, if they had
submitted tlieniselves to a .sound self-ap])lied di.scii)line of
mind, have become suci-essful experimental Philosopliers.
To 1 )r. liecker lie Avi'oto :
I was never able to make a fact my own without seein;j,- it ;
and the descriptions of the best works altogether failed to
convey to my mind such a knoAvledge of things as to allow
myself to form a judgment upon them. Jt was so with ?k'?"
things. If Grove, or Wheatstone, or Gassiot, or any other
told me a new fact, and wanted my opinion either of its value,
or the cause, or the evidence it could give on any subject, I
never could say anything until I had seen the fact. For the
same reason I never could work, as some Professors do most
extensively, liy students or pupils. All the Avork had to be
my own.
Of Faruday's social life and suiToundings during
his meridional and later period nnicli might be
Avritten. After his great researches of 1831 to 1836
scientific honours flowed in freely u})on him, especially
from foreign academies and universities; and the fanje
he Avon at home Avould haA^e brought him, had he
been so minded, an ample professional fortune and all
tlie artificial amenities of Society Avhich follow the
successful money-maker. From all such mundane
" success " he cut himself off' when in 1881 he decided
to altandon professional fee-earning, and to devote
liiiuself to the advancement of science. Probably the
tf-'uets of the religious body to Avhich he belonged
Avere a leading factor in coujpelling this decision.
Not having laid upon hiiu the necessity of providing
for a family, and accustomed to live in an unostenta-
INCOME AND EXPENDITURE. 245
tious style, he could contemplate the future without
anxiety. With his pension, his Woolwich lectures,
and his Trinity House appointment, Faraday was in
no sense poor, though his Roj^al Institution professor-
ship never brought him so much as £300 a year until
after he was over sixty years of age ; but on the other
hand, his private charities were very numerous. How
much of his income was spent in that way can never
be known ; for the very privacy of his deeds of kind-
ness prevented any record from being kept. Certain it
is that his gifts to the aged poor and sick must have
amounted to several hundreds of pounds a year ; for
while his income for many years must have averaged
at least £1,000 or £1,100, and his domestic expendi-
ture could not have inuch exceeded half that sum, he
does not seem to have attempted to save anything.
Nor did he grudge time or strength to do kindly
charitable acts in visiting the sick.
From about the year 1834 he resolutely declined
invitations to dinners and such social gaieties ; not, as
some averred, from any religious asceticism, but that
he might the more unrestrainedly devote himself to
his researches. " If," says Mrs. Crosse, " Babbage,
Wheatstone, Grove, Owen, Tyndall, and a host of
other distinguished scientists, were to be met very
generally in the society of the day, there was one man
Avho was very conspicuous by his absence — this was
Faraday ! His biographers say that in earlier years
he occasionally accepted Lady /iJavy's invitations to
dinner : but I never heard of his going anywhere, ex-
cept in obedience to the commands of royalty." He
did indeed occasionally dine quietly with Sir Robert
&
i^4G Michael KAKAi)AV.
Peel or Envl Russcli ; and of the Icn^^ public (llniiers
he attended, he enjoyed most the annual banquet ut'
the Ro3^al Academy of Arts.
Faraday does not, however, a[)pear to have had
. any very direct rehxtions with the world of art. Once
he was consulted by Lord John Russell as to the
rejnoval of Raphael's cartoons from Hampton Court
to the National ( Jallcry. His advice was adverse, on
account of the penetrating power of dust. Though a
sufficiently good draughtsman to prepare his own
drawings, lie had little or no knowledge of the
technicalities of painting. Yet his sensitive and
enthusiastic temperament had nmch in common with
that of the artist, and he enjoyed nuisic, especially
good music, greatly. In early life he played the Hute
and knew many songs by heart. He took bass
parts in concerted singing, and is said to liave sung
correctly in time and tunc. In his circle of
acquaintanceship Avcrc numbered several painters of
eminence — Turner, ]jandsccr, and Stan field. His
brother-in-law, Mr. (ieorge J:{arnard, the late well-
known water-colour artist, has written the following
note : — -
My iirst ami many following Hkctf^liiiig trips wltc inado
with Faraday and his wife. Storms excited his admiration at
all tinK's, and he was never tired of looking into the heavens.
He s:iid to me once, "i wonder you artists don't study the
light and colour in the shy jnore, and tiy nioi-e for eflfect." I
think this tiuality in Turner's drawings made him admire them
so much. He made Turner's acijuaintanee at Hullmander.s,
and afterwards often had applications from him for chemical
information about jtigments. Faraday always impressed u|)on
Turner and other artists the great necessity there Avas t(j
SCLEXCE, LITEUATUllE. AXD AUT. 247
experiment i>H' tlieiii>elve.s, putting washes and tints of all
their pigments in the bright sunlight, covering up on^^ half,
and noticing the effect of light and gases on the other. . . .
Faraday did not tish at all during these ci.-untry tri[ts, but
just rambled about geologising or botanising.
Earlier iu his career, Faraday and his brother-in-
law used to enjoy conversaziones of artists, actors, and
musicians at Hulhnandel's. Sometimes they went up
the river m HtiUmandel's eight-oar boat, camping
gipsy- wise on the banks for dinner, and enjoying the
singing of Sigxior Garcia and his wife and of his
daughter, afterwards Madame Malibran. From these
things, too. he withdrew very largely when he ceased
to dine out, though he still liked to hear the opera
and to visit the theatre. Curiouslv enough, he seems
to have had very little in common with literary men.
In the last half of the previous century there had
been many intimate relations between the leaders of
literature and those of science. The circle Avhich
incltided AVatt, Boulton, and Wedgwood included
also Priestley and Erasmus Darwin. In our own time
the names of Darwin, Huxley, Hooker, and Tyndall
are to be found in conjunction with those of Tennyson,
Browning, and Jowett. But the biographies of literary
men and artists of the period from 1S30 to 1850
bear few references to Faraday. He moved iu his
own world, and that a world very much apart from
literature or art. In his metht'd of working he was
indeed an artist, often feeling his Avay rather than
calculating it, and arriving at his conclusions by
wdiat seemed insight rather than by any direct process
of reasonino-. The discovery of truth conies abotit m
248 MICHAEL FARADAY,
iiumy Avays; and if Faraday's method in science was
artistic rather than scientific, it was amply jnstitied by
the brilhant liarvest of discoveries which it enabled
him to reap.
As is well known, Faraday never tt)ok out any
])atents for his discoveries : indeed, whenever in his
investigations he seemed to come near to the point
where they began to possess a marketable A'alue from
their application to the industries, lie left them, to
pursue his pioneering inquiries in other branches.
Ho sought, indeed, for principles rather than for
processes, for facts new to science rather than for
merchantable inventions. When he had made the
discovery of magneto-electric induction — the basis of
all modern electric engineering — he carried the re-
search to the point of constructing several experi-
mental machines, and then abruptly turned away
with these inenioraltle Avords : —
I have rather, hrtwever, been desirous of discoverinj:,^ new
facts and new relations dependent on magneto-electric induc-
tion than of exalting tlie force fif those already ftbtained ;
being assured that the latter would find their fall deveIo|)nient
hereafter.
Several times was Faraday known, when asked
about the possible utility of some new scientific dis-
covery, to quote Franklin's rejoinder : " AVhat is the
use of a Ijaby ? "
It is narrated of him that on one occjision, at a
Trinity House dinner, he and the JJuke of Wellington
had a little iriendl}- chat, in the course of which the
Duke advised Faraday to give his speculations " a
practical turn as i'ar as possible " — " a suggestion,"
PRACTICAL UTILITIES. 249
said Faraday, who ahvays spoke of the veteran with
pleasure, '■' iuU of wei^^-ht, coinino; from such a man.''
Fai-aday ^vas, however, the last to despise the iui-
portance of industrial apphcations of science, in his
un[.iui^lished manuscripts at the Royal Institution
there are some curious references to trials Avhich he
made of a meat-canning process, invented aliout 1S48
hy a Mr. i Joldner, of Finsburv. He also had fancies
for other domestic applications, includini^ wine-making.
He used himself to bind his own note-books. To a
]\Ir. AVoolnough, ^vlio had written a book on the
marbling of paper, he wrote a letter saying how much
interest he felt in the suljject, " because of its associa-
tions with m}' early occupation of bookbinding ; and
also because of the very beautiful principles of natural
})hilosophy which it involves." He even, on one
occasion, jtroduced a home-made pair of boots. His
devotion to the practical applications of science is
attested by his untiring work for improving the light-
liouses of our coast. It is believed that his death was
accelerated by a severe cold caught wdion on a visit of
lighthouse inspection during stormy weather.
Farada)' was never ashamed of the circumstance
of his having risen from a humble origin. In his
letters he not unfrequentlv alludes to things that
reo'iind him of his bookbinding experiences, or of
bo\'ish episodes in his father's smithy. Yet he had
none of the vulgar pride of ascent wliich too often
dogs the path of the self-made man. Severe self-
discipline and genuine humility prevented either
undue pioclamation or awkward reticence respecting
his early life. His elder brother Robert Avas a gas-
250 MHJHAEL FARADAY.
litter. Fararlay was not aslianied to help hiin to
secure work in his Lraclo, nor to give him the l)eneKt
of his scientiiic aid in perfecting ajij^liances for venti-
lating by gas-burners. The following characteristic
story Avas tohl by Frank Barnard : —
Jiobert was tljiougltout life a "warm Irieiid ami admirer of
his younger brother, and not a whit envious at .seeing himself
passed in the social scale by him. One day he was sitting in
the Royal Institution just previous to a lecture by the young
and rising lAiilosoplier, when he heard a couple of gentlemen
behind him descanting on the iinturrd gifts and rapid rise of
the lecturer. The brother — perhaps not fully apprehending
the purport of their talk— listened with growing indignation
while one of them dilated on the lowness of Faraday's origin.
''Why,' said the sjteaker, "I believe he was a mere shoeblack
at one time." Uobert could endure this no longer ; but tuin-
ing sharply round he demanded : " Pray, sir, did he ever black
your shoes?'' "Oh! dear no, certainly not," replied the
gentleman, much abashed at the sudden iu'iuisition into the
facts of the case.
In 1853 Faraday came before the public in a
novel manner— as the exposer of the then rampant
charlatanry of table-turning and spirit-rappijig. The
Atlievjrv/m for July 2nd contains a long letter from
him on table-turning. He experimentally investi-
gated the alleged phenomena as produced by three
skilful mediums in smvce^^ at the house of a friei.d.
His mechanical skill was more than a match, how-
ever, for that of the supposed spirits. When the
observers assemblerl around the table placed their
hands in the orthodox Avay upon the table-top, the
taljle turned, apparently without any effort on the
part of any one of the part). This was eminently
SPJUIT MEDICMS EXPOSED. 251
Siitisfactoi-}- for the spirits. J^ut when Far;idi\y
interposed between each hand and the table- top a
sinipjle roller-niechanisui which, if any iiidividual in
the circle appHed muscular forces tending to tuni it,
instantly indicated the fact, the table remained
immoA'able. Farada}^ wrote merely describing the
facts, and .sa3dng that the test apparatus was now on
public view at 122, Regent Street. He ends thus: —
I rniLst Ijring this long description to a close. I am a little
ashiimed of it, for I think, in the present age, and in this part
of the world, it ought not to have been required. Xeverthe-
le,-s, I ho]»e it may be usefuh There are ujany whurn I do not
expect to convince ; but I may be allowt^d to say that I cannot
undertake to answer such ol.jjections as luay be made. 1 stiite
Tjiy own convictions as an experimental philosopher, and find
it no more necessary to enter into controversy on this point
than on any other in science, as the nature of matter, or
inertia, or the magnetisation of light, on which I may difi'er
from others. The world will decide sooner or later in all such
cases, and I have no doubt very soon and coirectly in the
present instance.
This exposure excited great interest at the time,
and there w^as an active correspondence in TIte Times.
The spiritualists, instead of appreciating the services
to truth rendered by the man of science, railed
bitterly at him. Even the refined and noble spirit of
Mrs. Browning was so dominated by the superstition
of the moment that, as shown by her recently
published letters, she denounced Faraday in singularly
acrimonious terms, and taunted him lor shallow
iiiaterialisni ! What Faraday thought of the liubbtdj
evoked hy his action is best learned from a letter
252 MICHAEL FARADAY,
^vhicll he addressed three Aveeks later to his friend
Schonbein : —
I have not been at work except in turning the tables upon
the table-turners, nor should I have done that, but that so
many inquiries poured in upon nie, tJiat I thought it better to
stop the inpouring flood by letting all know at once what my
views and thoughts Avere. "Wluit a Aveak, credulous, incredulous,
uulielieving, snperstitious, bold, frightened, what a ridicidous
world ours is, as far as concerns the mind of man. How full
of inconsistencies, contradictions, nnd absunlitics it is. I
declare that, taking the average of many minds that have
recently come before me (and ajiart from that .spirit Avhich
God has placed in each), and acce|^ting for a moment tliat
average as a standard, I should tar prefer the obedience,
affections, and instinct of a dog before it. Do not whisper
this, however, to others. There is One above who w(^rketli in
all things, and who governs even in the midst of that misrule
to which the tendencies and i)OAvers of men are so easily
perverted.
He declined an invitation in 1855 to see mani-
festations by the medium Home, saying that he had
" lost too much time about such matters already."
Nine years later the Brothers Davenport invited him
to witness their cabinet " nianifestations." Airain he
declined, and added : " I will leave the spirits to find
out for themselves how they can move my attention.
I am tired of then:i."'
In this 3'ear he wrote to The Times respecting the
disgraceful and insanitary condition of the river
Thames. In Punch of the followdng week appeared a
cartoon representing Faraday presenting his card to
old Father Thames, wdio rises holding his nose to
avoid the stench.
AVith increasing;" ao-e the infirmity of loss of
memory made itself increasingly felt. He alludes
tVeqaently to this in his letters. To one friend who
upbraided him gently for not having replied to a
letter he sa3^s : "Do you remember that I foig'et ? "
T(t another he says he is forgetting how to spell such
words as " withhold " and " successful." To Matteucci,
in 1849, he bemoans how, after working for six weeks
at certain experiments, he found, on looking back to
his notes, he had ascertained all the same results
eight or nine months before, and had entirely
forgotten them! In the same year he wrote to Dr.
Percy :—
I cannot be on tlie Committee ; I avoid everytliing of that
kind, tliat I may keep my stupid liead a little clear. As to
being on a Committee and not working, that is worse still.
In 1859, in a letter to his niece, Mrs. Deacon, tilled
mainly with religious thoughts, he says : " ^Ly worldly
faculties are slippiug away day by day. Happy is it
for all of us that the true good lies not in them.'*
From the journals of AV alter White conies the
following anecdote under date December 22nd,
1858:—
Mr. Faraday called to enquire on the part of Sir Walter
Trevelyan whether a M8. of meteorological ob.servations made
in Greenland aa'OuIcI be acceptable. The question answeri'd, 1
expressed my pleasure at seeing him looking so well, and
asked him if he Avere Avriting a piqicr for the Ivoyal. He
shook his head. "No : I am too old.'' "To*.) old? Why, age
iirings Avisdom.^' " Ves, but one may overshoot the wisdom."
"You cannot mean that you have outlived your Avisdom ? "
"oomething Uke it, for my memory is gone. If 1 make an
experiment, I forget before tAvelve hours are over Avhether the
result was positive or negative ; and how can I Avrite a paper
2-34 MICHAEL rAKAPAV
wliile that is the c;ise .' X(t. 1 must content myself with
givin.ii' my lectures to children."
From anotlier sonrre wo loaru o\' a liitliorto un-
recorded incident which liappened to Mr. -loscph
Newton, tor some time an assistant in the Ixoyal
^[int. While arranging some precious material on
the Eoyal Institution theatre lectiu'e-table. previous
to a lecture on the !Mint and minting operations by
Professor Brande. Mr. Xewton noticed an elderl}^
spare, and very plainly-dressed individual Avatching
his ujovements. Imagining that this person was a
superior messenger ot the Institution, i\[r. NeAvton
volunteered some information as to the coinao-e of
gold. " I suppose." said the ]\lint employee, "you
have been some years at the Royal Institution ^ "
'■ Well, yes, I have, a good niany," responded the
dilapidated one. '■ 1 hope they treat you prettA'
liberally — -1 mean, that they give you a res]-)ectablo
■ screw,' for that is the main point." " Ah 1 1 agree
with you there. 1 think that the labourer is worthy
of his hire, and 1 shouldn't mind being paid a little
better." Mr. Xewton's surprise, on returning to the
l\oyal Institution in the evening, to tind that the man
Avhoni he had so recently patronised was none other
than the illustrious but modest ^lichael Faraday can
better be imagined than described.
A jirett}' instance, given <tn the authority of Lady
Follock, may be recorded of the feeling arouseil by
Faraday's presence when he retiu'ned to his accus-
tomed seat in the lecture-room of the Royal Institu-
tion, after a protracted absence occasioned by illness : —
HOXontS OFFERED AXD DECLTXED.
•'?n;
As soon as liis presence was recognised, tJie wlmle audience
rose simultaneously and burst into a si)ont;ineous utterance of
welcome, loud and long. Faraday stood in acknowledgment
of tliis enthusiastic greeting, with his tine head sliglitly bent ;
and then a certain resemblance to the pictures and busts of
Lord Nelson, which "was always ol)servable in his countenance,
was very apparent. His hair had grown white and long, his
fare had lengthened, and the agility of his movement was
gone. The eyes ]io hniger tlashed with the fire of the soul, but
they still radiated kindly thought ; and inL'tiaceable lines of
intellectual force and energy were stanjped ujion his face.
In 1857 he was offered the Presidency of the
Royal Societ}^ A painting preserved in the rooms
of" the Koyal Society records the scene "when Lord
AVrottesley, Grove, and Gassiot \vaited upon him as
a deputation from the Council, to press on him his
acceptance of the highest place "which science has to
offer. He hesitated and finally declined, even as he
had declined the suggestion of knighthood years before.
" Tyndall,' he said in private to his successor, " I must
remain plain Michael Faraday to the last; and let me
now tell you, that if I accepted the honour -which the
Royal Society desires to confer upon me, I could not
answer for the integrity of iny intellect for a single
3'ear." He also declined the Presidenc}^ of the Royal
Institution, which he had served for hfty years. His
one desire was for rest. " The reverent affection of
his friends was," said Tyndall, " to him infinitely more
precious than all the honours of official life. '
xlUusion has been made to F'araday's tender and
chivalrous rec^ard for his wife. Extracts from two
letters, written in 1849 and 1863 respectively, must
here suffice to complete the stor^' : —
2")() MH'UAKL FAltADAY.
lliniiitii;liaiii, 1 )r. Percy's :
Tliursday cs'i'iiin,^-, Sr])ti'iiilior 1.'^, \HVJ.
M\ Dkaiiest AViI'K,- 1 iiavojnst. iet't Di-. IVrcys liospitaJtlc
talilc to wriic to you, my licloved, tellin.i;- you liow I liavc lieeu
^■ettiii.L;- ou. I aiii wvy well, cxiH'jitin.i; a little faccaclie ; and
very kiudly ti't/atcil lua'c. Tliry ;ill lon.i;- luost. I'a.rncstly foi-
>'our iuh'soiicc, for Itotli Mrs. atnl l)i'. IVrcy ain*. auxions you
should ciMiK' ; and this I know, tiait, the lliin.'j,'s we liavo sci'it
would (h'li.'^lit yon, hut. tlu'u I donlit your jiowcrs of rnnuiiii;'
aliout. as we do ; aud tli(tu;.,di I Icuow that if time were i;iveii
>oii rould eujoy them, yet to press tlie uiatter into a day or
two would he a fidlure. V.esides this, aflei' all, (hei'e. is uo
jileasnre like tlie trauijuil plea.sures of home, and liri'e - even
liere — tlie iU(*meut I lea\'e the tahle, L wisli I were with you IN
(H'ti'rr. Oh! what hajipiuess is ours! My ruus into the
"worhl in this way only serve to uiake rue esteem that hapjiiness
the uiore. I mean to be at houie (ni Saturday uif-ht, liut it
may be late, hrst, so do not be sui-prised at that ; for if [ ean, I
should like to i;'o on an excui'sion to the I )udley ea,verus, and
tliM.t W(tuld take the day
Wi'iti,'. to uie, dearest. 1 shall .;;et your hotter on Satnrday
luorniiig, or perhaps before.
Love to father, Margery, aud Jenny, and a llnaisand loves
to yourself, dea.rest,
J^'roui yf)ur aiieetionate husband,
_ M. Fai; \h.\\.
5, Claremout (iardeus, (JIa.sgow :
Monday, August 14, I8(i;i.
I )l:AUl•:.■^T, Ilei'e is the fortidght complete siiu'o 1 left you
and the thoughts ol my return to oxr lionic crowd in strongly
ujiou my mind. N(.it tliat Ave are in any way uneared for, or left
by our dear friends, save as i may desire for our own retire-
uieut. Everybody has overfloAved Avith kindness, but you
know their ]uanner, aud their desire, by your ftwu experience
with uic.
TJIE WJFE ANJ> 'J'HE (,)UEEX. 2o /
I long to see you, dearest, and to talk over things t<:>getlier,
and call to mind all the kindness I have received. My head is
full, and my heart also, bat my recollection rapidly fails, even
as regards the fiietids that are in the room with uie. You will
have to resume your old function of being a iiillo\\' tmuymind,
and a rest, a hapjiy-raaking wife.
^ly love to my dear Mary. I expect to ^nd you together,
but do not assume to know how things may be.
Jeannie's love with mine, and also Charlottu's, and a great
many others which I cannot call to miiLd.
Duarest, T long to see and be with you, A\hether together ur
sejiarate.
Your husband, vury affectionate,
M. Faraday
In ISo^S the Queen, at tlie suggestion of Prince
Albert, "who nuich esteemed and vahied Faraday's
genius, placed at his disposal for life a comfortable
house on the green near Hampton Court. Faraday's
only hesitation m accepting the offer was a doubt
Avhether he could afford the needful repairs. On a
hint of this reaching the Queen, she at once directed
that it should be put into thorough repair inside and
out. He still kept his rooms at the Royal Institution,
and continued to live there occasionally.
With the increasing infirmities of age, his anxieties
for his wife seemed to be the only trouble that marred
the serenity of his thought. Lady Pollock's narrative
gives the following particulars : —
Sometimes he was depressed by the idea of his wife left
without kin — of the partner of his hopes and cares deprived of
him. She had been the tirst love of his ardent soul ; she was
the last ; she had been the brightest dream of his youth, and
she was the dearest comfort of his age ; he never ceased for an
11
258
iMECHAEL FAHADAV.
instant to feel liimself happy with her ; and he never for one
Ijour ceased to care for her happiness. It was no wonder, then,
that he felt anxiety about her. But he would rally from such
a trouble with his great religious trust, and looking at her
Avith moist eyes, he would say, " I must not be afraid ; you
will be cared for, my wife ; you will be cared for."
Fig. 22. — fauaday's h
DME AT HAMPTON COURT.
There are some who remember how tenderly he used to
lead her to her seat at the Eoyal Institution when she was
suffering from lameness ; how carefully he used to support her;
how watchfully he used to attend all her steps. It did the
heart good to see his devotion, and to think what the man was
and Avhat he had been.
Gradiuilly his powers \vaned. He gave his last
juvenile lectures at Christmas, 1860 ; and in October,
1861, being now seventy years of age, he resigned his
CLOSE OF SCIEXTIFIC OAriEER. 250
Professorship, while retaining the superintendence of
the laboratory. "Xothino','' he wri.'te to the managers,
'• wijuld make me happier in the things of this life
than to make some scientihc discoverv or d'.-^'ii^lop-
ment, and hx that to justifv the Board in their desire
to retain me in riiy position here." His last research
in the hiborator}" was made on March 12, l>Sij2. On
June 20th he gave his last Friday night discourse — on
Siemens's gas furnaces. He had, as his notes show,
already made up his mind to announce his retirement,
and the lecture was a sad and touching occasion, for
the failure of his powers was painfully evident. He
continued for tAvo years longer, and with surprising
activity, to work for Trinity House on the subject of
lighthouse illumination by the electric light. In 18G5
he resigned these duties to Dr. TyndaU. In 1864 he
resigned his eldership in the Sandemanian church.
In March, 1865, he resigned the position of super-
intendent of the house and laboratories of the Ro3'al
Institution. He continued to attend the Trida}*
evenin^c nieetinf^s : but his tottering'' condition of frame
and mind Avas apparent to all. All through the
wdnter of 1865 and 1866 he became very feeble. Yet
he took an interest in Mr. Wilde's descrip)tion of his
new magneto-electric machine. Almost the last
pleasure he showed on any scientific matter was when
viewing the long spark of a Holtz's influence machine.
He still enjoyed looking at sunsets and storms. All
through the summer and autumn of 1866 and the
spring of 1867 his physical powers waned. He was faith-
fully and lovingly tended by his wife and his devoted
niece, Jane Barnard. He was scarcely able to move,
260 MICHAEL FAKAOAY.
but his mind " overtlowed " with the consciousness
of the affectionate regard of those around him. He
gradually sank into torpor, saying nothing and taking
little notice of anything. Sitting in his cdiair in liis
study, he died peacefully and painlessly on the
2Gth of Anoust, INllT. On the 30th of August
he was quietl}' buried in Highgate Cemeter3\ his
remains being connuitted to the earth, in accord-
ance with the custom of the religious bod}^ to wdiicli
he belonged, in perfect silence. None but personal
friends Avere present, the funeral being by his own
verbal and written wishes strictl}' simple and private.
A simple unadorned tombstone marks the last resting-
place of Michael Faraday.
CHAPTER YIL
VIEWS UN THE PURSUIT OF SCIENCE AND ON
EDUCATION.
Betaveen Faraday and the scientific men of his time
there subsisted many various relations. The in-
fluence which he exerted as a lecturer and as an
experimental investigator was unique ; but, apart
from such influences, those relations were mainly
confined to individual friendships. With the organ-
isation of science he had relatively very little to do.
AVe have seen how highly he prized the honour of
adniission to the Fellowship of the Royal Society ;
and it remains to be told of the gratification with
which he accepted the scientific honours which he
received from almost every academy and university
in Europe. Yet he took little part in the work of
scientific societies as such. Four years after his
election as F.R.S. he served on the Council, and he
remained on*till 1X31. He served asirain in 1833 and
LS35. He was not, however, satisfied with the
management of the Royal Society, nor with the way
in which its Fellowship was at that time bestowed
on men who had no real claims on science, but
were nominated through influence. Echoes of this
262 MiniAKI. FAItADAY.
discontent arc to be found in varictus pnniphlots of the
day by ]\[oll. l^abbagw South, and othors. i-'avaday,
"wlio oditctl Clod's pamphlet, on the " decline ot'
Science,'" is beheved to have had an even larLjei* share
in its production. In 18;U) the ready scientific men
amono-st the Fellows desired to place Sir John
llerschel as President ; the less scientific preferred
the l)nke ot" Sussex. Faraday took the unusual step
ot" sj^eakini;" on the (luestion, advocatiuL;' tlie principle
that emineni'c in science should be the sole ipiali-
lication tor the l^residericy. Al the same meeting'
Herschel moved, and b'aradaA' seconded, a, plan for
retbrnun!.;' the Council h\ nominatin;^" a list, nl' tifty
Fellows trt)m whose number the C'ouncil should be
chosen. The\' carried their plan. ;uul Faraday's name
Avas amongst those so selected to serve. F)Ut the
]>resitlential election went in favour of t.he Didvo of
Sussex by 111) to 110 votes. After 1S;^5 Faraday
never served ag'ain on the t'onncil. In lS4;i he wrote
to Matteucci : —
I think you are awaii' that I lia^c not alli'iuled at thr
lioyal Society, either meetings or eouneil, for some years. Ill
heaUh is one reason, and another that I do not like tlie
l>iesent eoii.stitntioa of it, and want to restrict it to scientific
men. As these my (iiiinions are not a.cce]ttal)K', I Imve
>\itlub'awn from any management in it (still sending scientific
eominunieations if 1 discover anything I lliink worthy). This,
of course, deprives me of power theru
Two months eai'licu' he wrote to th'ove, wht) at
that time was carryino- out the lon^-needed reforms,
sympathising, but detdining t.o co-operat,o : —
i;el-^()1!M in the j;oval society. '2fJ-'j
Royal Institution,
December 21, 1842.
My dear (tRove,^ . . . As to the lioyal Society, you
know my feeling- towards it is for what it has been, and I hope
ma}^ be. Its present state is not Avholcsome. You are aware
that I am not on the council, and have not been for years, and
have been to no meeting there for years ; but I do hope for
better times. I do not wonder at your feeling-— all I meant to
express was a wish that its circumstances and character
should ini})rove, and that it should again become a desirable
reunion of all really scientific men. It has done much, is
now doing much, in some parts of science, as its magnetic
observations show, and I hope will some day become alto-
gether healthy.
Ever, my dear Grove, yours sincerely,
M. Faraday.
Thougii he continued down to 18G0 to send
researches for publication to the Eo3'al Societ}^, he
seldom attended its meetings.* He was not even
present m November, 1845, on the occasion of the
reading of his paper on the action of the magnet on
hght. In 1857 he declined the Presidency, though
urged by the unanimous wish of the Council, as
narrated on p. 225.
Though in the meridian of his active life, he took
'"' Once again did Faraday intervene in Koyul iSociety affairs at
the crucial time when Lord Rosse was; elected President in 1S4S.
The following excerpts from the journals of Walter White show the
cause :—
" Xovemher 25th. — There have heen many secret conferences this
week— much trimming and time-serving. Alas fur human nature I "
" November 30th. — The eventful da)-, the hallot hegim. Mr.
Faraday made some remarks ahout the list,"
264 MimiAKI. FAUAUAY.
no part in the toundin^u;- of tlio Ikitisli Association
in 1831, but Avas at tlio Oxford meeting in 1832,
being one of the four sciontitic men (p. 05) selected
to receive the honorary degree of ].).(! \j. on that
occasion. Ho also conununicated a paper on Elcctro-
clieniical 1 )ecoiupositiou to the IJ.A. meeting at
(Jambridgc in 1S33. He acted as president of tlie
Chemical Section of the Asso(nation in 1.S37 at
Liverpool, and in 1 'S4(i at S(jutham])ton ; and Ik^
was chosen as vi(X!-[)resident of the Associjition
itself in the years LS44, at York (p. 224); 1.S49,
at Birmingham (p. 250); and 1.S53, at Hull, lie
delivered evening discourses in 1.S47, a.t Oxford, on
Mametic and I)iamai?'netic IMienomcna : and in 1(S49,
at ]]irminghaiu, on Mr. (iassiot's llattery. He also
contributed t(.) the ]>rocce(hngs at the meetings at
Ipswich in 1S51 and at Liverpool in 1.S54.
His comparative aloofness from scientific organi-
sations arose probably from the exceedingly individuid
nature of his own researches— to which allusion
was made on p. 242 — rather than from any lack of
sympathy. Ho had no jcaloiisy of co-operation in
science. To Tyndall, then at Marburg, he wrote in
1850 rejoicing at the circumstance that tlie work
on the niagnetic properties of crystals was being
taken up by others. '' It is Avonderful," he says,
'■ how nuich good results from different pei'sons
working at the same matter. Each one gives views
and ideas new to the rest. When science is a
republic, then it gains ; and though I am no re-
publican in other luattcrs, I am in that." Other
causes there Avere, doubtless, tending to liis isolation.
PraORITY IN SCIENTIFIC DJSOOVEUY. 265
amongst them an old jealousy, noAv long dead, against
the RQjal Institution on the part of some of the
Fellows of the Ro3'al Society. Above all, probably,
Avas his detestation of controversy.
Priority in scientific discovery was a matter which
deeply concerned one whose life was devoted to
scientific pioneering. To any question as to scien-
tific priority between himself and other workers he
was keenly sensitive. This was, indeed, natural in
one who had voluntarily relinquished fortune, and
retired from lucrative professional work, in the sole
and single aim of advancing natural knowledge.
His single-minded and sensitive nature made him
particularly scrupulous in all such matters, and his
early experiences must have added to the almost
excessive keenness of his perceptions. Having had
in 1823, when still merel}' assistant to Davy, to bear
the double burden of a serious misunderstanding
Mvith Dr. AVollaston as to the originality of his dis-
covery of the electro-magnetic rotations, and of a
serious estrangenrent from his master arising out of
the liquid chlorine discovery — an estrangement which
threatened to cause his election to the lioyal Society
to be indefiniteh' postponed— he was in later life
especially precise in dating and publishing his own
researches. In 18*31 there arose, concerning his great
discover}^ of magneto -electric induction, a curious
misunderstanding. His discovery was, as we have
seen, made in September and October. He collected
his results and arranged them in the splendid me-
moir — the first in the series cf '' Experimental
Researches in Electricity " — which was read at the
-66 MICHAEL FARADAY.
Royal Society on Xovember 24-th. The resnrae of
his work, -which he wrote five days later to Phillips, is
given on pages 114-117. A fortnight later he wrote
a shorter and hasty letter in the same way to his
friend, M. Hachette of Paris — a letter which Faraday
subsequently well termed " unfortunate," in view of
the consequences that followed. M. Hachette, a week
later, communicated Farada3''s letter to the Acadeuiie
des Sciences on December 26th. It was published
in Le Terivps of December 2Sth. At that date the
complete memoir read to the Ptoyal Society was not
yet printed or circulated. The consequence was that
two Italian ph3^sicists, MM. Nobili and Antinori,
seeing the brief letter, and '" considering that the
subject was given to the philosophical world for
general pursuit," immediately began researches on
magneto-electric induction in ignorance of Faraday's
full work. Their results they embodied in a paper.
in which they claimed to have "verified, extended.-
and, perhaps, rectitied the results of the English
philosopher," accusing him of errors both in ex-
periment and theor}^, and even of a breach of good
faith as to what he had said about Arago's rotations.
This paper they dated January 31st, 1832 ; but it
was published in the belated number of the Avtologia
for November, 1831, where its appearance at an
apparently earlier date than Faraday's original
paper in the Fhiloscqjhical Transactions made many
Continental readers suppose that the researches of
Xobili and Antinori preceded those of Faraday. In
June, 1832, Faraday published in the Fhilosopltical
Magazine a translation of Nobili's memoir, Avith his
PltHyRlTY IX PUBLICATION. 267
own annotations; and later in the year he wrote to
Ga}^ Lnssac a long- letter on the errors of Nobili
and Antinori. He showed how, in spite of his efforts
to clear up the misunderstanding, in spite of his
having sent several months previously to MM. Nobili
and Antinori copies of his original papers, no cor-
rection or retractation had been made by them ; and
he concluded b}^ a dignified protest that none might
say he had been too hasty to write that which might
have been avoided. It may be taken that the rule
now recognised as to priority of scientific publication
— namely, that it dates from the day when the dis-
coverer communicates it formally to any of the
recognised learned societies — was virtually established
by Faraday's example. It will be remembered that
writing to De la Rivo in 1845, to tell him of his
diamagnctic discoveries, he begged him to keep the
matter secret, adding; " I ought (in order to ])reserve
the respect due to the Royal Society) not to write
a description to any one until the paper has been re-
ceived or even read there." To younger men he incul-
cated the necessity of proper and prompt publication
of their researches if they would reap the benefit of
their work. To Sir William Crookes, then a rising
young chemist, he said : " Work, Finish, Publish."
AVriting in 1858 to Professor Mattcucci, who had been
annoyed with him for allowing Du Bois Reymond,
with whom Matteucci had had some controversy
about priority, to dedicate his book to him, Faraday
says : " Who has not to put up in his day with
insinuations and misrepresentations in the accounts
of his proceedings given by others, bearing for the
2GN ]MI(.'IIAKI- KAKADAV.
time tlio present injustice, which is often uninten-
tional, and often orio'inates in lia.sty temiu^r, a.nd
conimittiuL;- his fame and eliaraet.er to the judgment
of the men of his own and future time T' . . .
"I see that tliat moves. 3'ou whicli would move mo
most — namely, l-he imjMitation of a want <)f i^-ood
faith— and I conliidly sym]tathisc with any one who
is so ehar^'cd unjustly. Such cases have seeuKMl to
mc almost the only ones for wliich it is worth while
enterinu^ into c.ontrt)versy. " . . . "These ])olemi('s
of the scientific world ;ire very unfortuna,tc (,hin<^\s;
tliey form the i^a'cat stain to which tlie hca.utiliil
editic(^ of scientitic truth is suhjeet. A ir. Iliof
■I umidhlc V
Controversy whether in reli^^'ion oi* sf^it^ice was to
him alil\(^ dete-stahU^ lie look no pai't in |)ohl,ics. A
letter to Tyndall (see" Faraday as a Discoverer," p. :i!'),
wi'itten after the latter had told him of a rather hnitcd
(hseussion at the Jiritish Asso(;iation nu^etinL,'' in lsr>5,
speaks of his own efforts at forhearanee. Jh?. says: —
'I'licsc , Invent mocliii,L,^s, f)f wliicli I lliink viny well aItn;^i'.Un',r,
;"i(l\';ilir(' science, cliieliy 1 ly ln'iii,i;iM,i;' scieiitillc men togctlief iiiii!
niakiiiK tlieiu to know and lie frienits with each olkev ; and i
am sorry when that is not the effect in every jitu't of thi-ir
course. . . . The |-eul Irnth never fails ultimately to
il]i]iear. . . It is better to he hiind to llii; resnils of
]iartisanshi]t, and (|uii'k to see ;;iM>d will. < )ne has more
lia]i|iiness in mieself in endeavtairini; to follow the thin,L,^s Ijia.t
make for |ieiice. \ nii can hardly inia,gine Jiow uftc^n I have
lieea heated in jirivate when ojijiosed, as I have tlion^lit nn-
jastly and superciliously, and yet \ ha\e slriven, and snccei^led
I hnpe, in keepiii.L,^ down replies of I he like kiiiil. And I know
I have never lost hy it.
HATRED OF 0()NTH(.)\'EKSY. 269
J)ui'ing the yeiws when ho was examining the
apparatus of rival inventors for Hghthouse illumina-
tion, ho Could cahnly hoar them (.lescrihcd as Mr. So-
and-So's electric lii^hts, all the while knowino- that it
was his own discovery of magneto-electric induction
which had made the mechanical production of electric
light possible. Yet he hred up if anyone dared to
revive the priority dispute between Davy and Stephen-
son as to the invention of the safety lamp. " Dis-
graceful subject," was his own connnent. In his
dispute with Snow Harris as to the design of lightning-
rods, in which, as it is now known, Snow Harris was
right : in his dispute with Airy over the curved lines
of force ; in his minor difhculties over Hare's pile and
Becquerel's magnetic observations, none could either
assert his own position with more simple dignity, nor
admit with o'reater frankness the riy-hts of his rival.
To Hare he Avrote : —
You must excuse uie, however, for several reasons from
answering it [Hare s letter] at any length ; the tirst is my
distaste for controversy, which is so great that I would on no
account our correspondence should acquire that character. I
have often seen it do great harm, and yet remember few cases
in natural knowledge where it has helped much either to pull
down error or advance truth. Criticism, on the other hand, is
of nmch value.
When we reflect how^ large a part of his experi-
mental researches was devoted to establishing the
relations betAveen the various forces of nature, we
cannot but think that Faraday must have regarded
with somewhat mixed feelings the publication in 1846
of Sir AYilliam Grove's volume on the Correlation of
270 MICHAEL FARADAV.
Forces. He bud, in June, 1834, given a course of
lectures on the mutual relation of clieuiioal and
electrical phenomena, and had dealt therein with the
conversion of chemical and electrical power into heat,
and had speculated on the inclusion of gravitation in
these mutual relations. In 1858 Faraday marked the
old lecture notes of these lectures "with his initials,
and endorsed theui with the words '' Correlation of
Physical Forces." Probably none rejoiced more than
he that Grove had undertaken the work of popularising
the notion which for a score of years had been familiar
to himself. Yet he was keen to resent an unjust
reflection, as is shown by his letter to Richard Phillips,
republished in Vol. II. of the " Experimental Re-
searches," p. 229, respecting Dr. John Davy's Life of
Sir Humphry.
Farada)^ has himself left on record (p. 10) that when
he wrote to Davy asking to be taken into his employ-
ment, his motive was his desire " to escape fronr trade,
which I thought vicious and selfish, and to enter into
the service of Science, which, I imagined, made its
pursuers amiable and liberal." Davy had smiled at
this boyish notion, and had told him that the experi-
ence of a few 3'ears would correct his ideas. Years
afterwards he spoke of this matter to Mrs. Andrew
Crosse in an interview Avhich she has recorded : —
After viewing the ample appliances for experimental
research, and feeling much impressed by the scientific atmo-
sphere of the place, 1 turned and said, "Mr. Faraday, you
must be very happ}^ in your position and with your pursaits-
which elevate you entirely out of the meaner aspects and
lower aims of common life."
HOXOUUS AKD TITLES. 271
He filiook his head, and with that wonderful mobility
of countenance which was characteristic, his expression of
joyousness chati,i:,'ed to one of profound sadness, and he replied :
"When I quitted business and took to science as a career,
I thought I had left behind nie all the petty meannesses
and stuall jealousies which hinder man in his moral progress ;
but I found myself raised into another sphere, only to find
poor human nature just the same everywhere — subject to
the same weaknesses and the same self-yeeking, however
exalted the intellect."
These were his words as well as I can recollect ; and,
looking at that good and great man, I thought I had never
seen a countenance which so impressed me with the character-
istic of perfect unworldliness.
Probably few men have ever been recipients of so
many scientific honours as Faraday. Beginning in
the year 1828 witli his election as a corresponding
member of the Academic des Sciences of Paris, and as
an honorary member of the Cambridge Philosophical
Society, the hst of his diplomas and distinctions —
some ninety-seven in number — ended in 1SG4 with
his election as Associate of the Ptoyal Academy of
Sciences of Naples. It included honours from almost
every academy and university of Europe. These
honours Faraday valued very highly ; and whilst he
consigned his various gold medals to a mere wooden
box, his diplomas were kept with the utmost care in a
special diploma book, in which they were mounted
and indexed. To Mr. Spring Rice, who in 1838 asked
him for a list of his titles, he replied, enclosing the
hst, and adding this remark : " One title, namely that
of F.R.S., was sought and paid for ; all the rest are
spontaneous offerings of kindness and goodwill from
272 MICHAEL FARADAY.
the bodies naiuecl." Years afterwards ho was asked
by Lord Wrottesley to advise the Govei-ninent as to
how the position of science or of the cultivators of
science in England might bo improved. The letter
is so characteristic that it cannot be spared : —
Royal [ij^titutioii : March 10, 1854.
My Lord, — I feel unfit to give a deliberate opinion on the
course it might Ije advisable for the Government to pursue if
it were anxious to improve the position of science and its
cultivators in our country. ^ly course of life, and the circum-
stances which make it a liappy one for me, are not those of
]»ersoiis Avho conform to tlie usages and habits of society.
Througli the kindness of all, from my Sovereign dowuAvards. I
have that which supplies all my need ; and in respect of
honours, I have, as a scientific man, received from foreign
countries and sovereigns those wdiich, belonging to very limited
and select classes, surpass in my opinion anything that it is in
the })0\ver of my own to bestow\
I cannot say that I have not valued such distinctions ; on
the contrary, I esteem them very highly, but I do not think I
have ever worked for or sought after them. Even w^ere such
to be now created here, the time is past wdien these would
possess any attraction for nie. . .
AVithout thinking of the eU'ect it might have upon distin-
guished men of science, or upon the minds of those who,
stimulated to exertion, might become distinguished, I do
think that a government should, /or its oivn sake, honour the
men who do honour and service to the country. I refer now
to honours only, not to beneficial rewards. Of such honours,
I think, there are none. Knighthoods and baronetcies are
sometimes conferred with such intentions, but I think them
utterly unfit for that purpose. Instead of conferring distinc-
tion, they confound the man who is one of twenty, or perha].is
fifty, with hundreds of others. They depress rather than
exalt him, for they tend to lower the especial distinction of
mind to the commonplace of society. An intelligent country
HOW SCIENCE CAX BE HONOURED. 273
ou^llt to recognise tlic scientific men amongst its people as a
class. If honours are conferred n[)on eminence in any class, as
that of the law or the army, they should be in this also. The
aristocracy of the class should have other distinctions than
those of lowly and high-born, rich and poor, yet they should
be such as to be worthy of those whom the sovereign and the
country should delight to honour ; and, being rendered very
desirable, and even enviable, in the eyes of the aristocracy by
birth, should be unattainable except to that of science. Thus
much, I think, the Government and the country ought to do,
for their own sake and the good of science, more than for
the sake of the men Avho might be thought worthy of such
distinction. The latter have attained to their fit place,
whether the community at large recognise it or not. . . .
I have the honour to be, my lord, your very faithful
servant,
M. Faraday.
To Professor Andrews lie wrote in 184o in a
similar strain : —
I have always felt that there is something degrading in
ottering rewards for intellectual exertion, and that societies or
academies, or even kings and emperors, should mingle in the
matter does not remove the degradation, for the feeling which
is hurt is a point above their condition, and belongs to the
respect which a man owes to himself. . . . Still, I think
rewards and honours good if properly distril)uted ; but they
should be given for what a man has done, and not offered for
what he is to do.
When a friend wrote to him on hearing a rumour
that he had hirnseh' been knighted, his reply,
published years after in the London Revieiv, was : " I
am happ3^ that I am not a Sir, and do not intend (if ii.
depends upon me) to become one. By the Prussian
s
274 MICHAEL FAEADAY.
knighthood* I do feel honoured: in the other I
should not."
On one occasion he commented rather sarcasti-
cally upon the British Government and its stinginess
as compared with those of all other civilised countries
in its aids to scientific progress. This complaint is
equally justified to-day. To niany it may be news
that England pays to its Astronomer Royal — who
must obviously be a person of very high scientific
qualifications — a salary less than those paid to the
five assistant under-secretaries in the Colonial and
Foreign Offices ; less than that paid to the sergeants-
at-arms in the Houses of Parliament : less than that
paid to the person appointed Director of Clothing
in the War Office. Enlicchtened Encrland !
Faraday did not deem the pursuit of science to be
necessarily incompatible with what he termed " pro-
fessional business" — that is, expert work. Until the
day when he abandoned all professional engagements,
so as to devote himself to researches, he had been
receiving a considerable and growing income from
this source. But he objected to the indignities to
which this work exposed him from lawyers, who
would not understand that he took no partisan view.
He could not endure the browbeating of cross-
examining counsel. The late Lord Card well was
witness to a gentle but crushing reproof Avhich he
once administered to a barrister Avho attempted to
bully him. A writer in the British Qao/rtcrbj Review
" He was a Cheviiliur of the Prussian Order of Merit, also Com-
mander in the Legion oE Honour, and Knight Commander of the
Order of St. Maurice and St. Lazanis.
UXrVERSlTY DEGREES IN SCIENCE. 275
attributes to a specific case his determination to
cease expert work.
He gave evidence once in a judicial case, when the scientific
te.stijuouy, starting from given premises, was so diverse that
the presiding judge, in summing up launched something like
a reproach at the scientific witnesses. " Science has not shone
this day," was his lordship's remark. From that time forth no
one ever saw Faraday as a scientific witness before a law
tribunal.
Amongst the honours received by Farada}^ there
was one of which, in 1S3S, he said that he felt it
equal to any other he had received — namely, that of
Member of the Senate of the University of London,
to which position he was nominated in 1S36 by the
Crown. For twenty-seven 3^ears he remained a
senator, and when, in 1859, the project for creating
degrees in science was on foot, he was one of the
committee who drew up a report and scheme of
examiiiation for the Senate. To the Rev. John
Barlow he wrote on this matter: —
The Senate of the University accepted and approved of
the report of the Conunittee for Scientific Degrees, so that
that will go forward (if the Government approve), and will
come into work next year. It seems to give much satisfaction
to all who have seen it, though the subject is beset with
difficulties; for when the depth and breadth of science came
to be considered, and an estimate was made of how much a
man ought to know to obtain a right to a degree in it, the
amount in words seemed to be so enormous as to make me
hesitate in demanding it from the student ; and though in the
D.S. one coukl divide the matter and claim eminence in one
branch of science, rather than good general knowledge in all,
still in the B.S., which i.s a progressive degree, a more extended
though a more superficial acquaintance seemed to be reiiuired.
In fact, the matter is so new, and there is so little that can
270 MH'UAEL FAUAJJAV.
serve as a previous expei'ieuce in the iounding and arraii;,dii;;j
these degrees, that one must leave the whole eiideavoiir to
shape itself as the practice and experience accumulates.
When, in 1863, his feebleness impelled him to
resign this position, he wrote to Dr. Carpenter : —
Tlje ]iosition of a senator is one that should not be held
by an inactive man to the exclusion of an active one. It has
rejoiced my heart to see the jtrogress of tlte University, and
of education under its inliuence and power ; and that delight
I hope to have so long as life shall be spared to me.
He had little sjnnpathy with either text - book
science or with mere examinations. " I have far
more confidence," he wrote, " in the one man who
works mentally and bodily at a matter than in the
six who njerely talk about it. Nothing is so good
as an experiment which, whilst it sets error right,
U'ives an aljsolute advancement in knowled'i^e." In
another place he wrote : — " Let the imagination go,
guarding it by judgment and principles, but holding
it in and directing it by expjerinient." For book-
learned chemistry and mere chemical theory, apart
from expjerirnental facts, he had an undisguised con-
tempt, Writing to General Portlock on the subject
of chemical education, he stated that he had been
one of the Senate of the University of London
appointed to consider especially the best miethod of
examination. They had decided on examination by
papers, accompanied by vivd voce. " We think," he
added, '■ that no numerijcal value can be attached
to the rjuestions, because eveiything depends on hoi'j
they are o/iisv:ered!' Then, referring to the teaching
at AVoolwich, he says, "My instructions always have
SCIENCE AND THE UNIVERSITIES. 277
been to look to the note-books for the result."
"Lectures alone cannot be expected to give more
than a general idea of this most extensive branch
of science, and it would be too much to expect
that young men who at the utmost hear only fifty
lectures on chemistry should be able to answer with
much effect, in Avriting, to questions set down on
paper, when we know by experience that daily work
for eight hours in practical laboratories for tJiree
■months does not go very far to confer such ability."
He had, at an earlier date, declined to be ap-
pointed as examiner in the University. He had
previously declined the professorship of che]nistry
in University College ; and he had also declined
the chemical chair in the University of Edinburgh.
This was not, however, from any want of sympathy
with university work, or faikire to appreciate the
ideal of a university as a seat of learning. Writing
to Tyndali, in 1851, about another university — that
at Toronto — he said : " I trust it is a place where
a man of science and a true philosopher is required,
and where, in return, such a man would be nourished
and cherished in proportion to his desire to advance
natural knoAvledge."
At the same time he had an exceeding repugnance
to the custom of expecting candidates for professorial
chairs to produce " testimonials " of their qualifica-
tions. When his intimate friend Richard Phillips
was a candidate for the very chair which Faraday
refused at University College, Faraday declined on
principle to give a testimonial " I should indeed
have thought," he added, " his character had been
:^7.S MICHAEL FAKADAV.
known to be such that it would rather have been
degraded than estabKshed b}^ certificates."
Similarly, in 1851, he told Tyndall, then an
applicant for the Chair of Physics at Toronto, that he
had in every case refused for many years past to give
any on the application of candidates. " Nevertheless,
he added, " I wish to say that when I am asked about
a candidate by those Avho have the choice or appoint-
ment, I never refuse to answer."
On general education, Faraday's ideas were much
in advance of his time. From the epoch when as a
young man he lectured to the City Philosophical
Society on the means of obtaining knowledge and on
mental inertia, down to the cluse of his career, he
consistently advocated the cultivation of the experi-
mental method and the use of science as a means of
traininsi' the faculties. A concise account of his views
is to be found in the lecture he gave in 1854 before
the Prince Consort on " Mental Education," a lecture
which prescribes the self-educating discipline of
scientific study and experiment as a means of correct-
ing deficiency of judgment. It included a powerful
plea for suspense of judgment and for the cultivation
of the faculty of proportionate judgment. In 1SG2
he w^as examined at some length by the Ptoyal Com-
missioners upon Public Schools. With them he
pleaded strongly for the introduction of science into
the school curricula : and wdien asked at what age it
mio-ht be serviceable to introduce science-teachinof,
rephed : " I think one can hardly tell that until after
experience for some few years. All 1 can say is this
that at my juvenile lectures at Christmas time I have
SCIENCE IN EDUCATION. 279
never found a child too young to understand intelli-
gently Avbat I told him ; they came to me afterwards
with questions which proved their capability."
One passage from the close of a lecture given in
185S deserves to be recorded for its fine appreciation of
" the kind of education which science offers to man " : —
It teaches us to be neglectful of nothing, not to despise the
A/iKfJl l>eginni]igs— they yu'ecede of necessity all great fhiuf/!^.
. . . It teaches a continual comparison of the i^ntaU (Did
f/reat, and that under differences alnntst approaching the
iiiHnite, for the small as often contains the great in princijile
as the great does the small ; and thus the mind becomes
comprehensive. It teaches to deduce iirinciples carefully, to
hold them firmly, or to suspend the judgment, to discover and
obey !(.(/'', and by it to be bokl in applying to the greatest what
we know of the smallest. It teaches us, first l)y tutors and
books, to learn that Avhicli is already known to others, and
then by the light and methods which belong to science to
learn for ourselves and for others ; so making a fruitful return
to man in the future for that which we have obtained from tlie
men of the past. Bacon in his instruction tells us that the
scientific student ought nnt to be as the ant, who gathers
merely, nor as the spider who spins from her own liowels, l)ut
rather as the bee who both gathers and produces.
All this is true of the teaching afforded by any part of
physical science. Electricity is often called wonderful, beautiful ;
l>ut it is so only in common with the other forces of nature.
The beauty of electricity or of any other foi-ce is not that the
power is mysterious, and unexpected, touching every sense at
unawares in turn, but that it is under iam^ and that the taught
intellect can even now govern it largely. The human mind is
placed above, and not beneath it, and it is in such a point of
view that the mental education aH'orded by science is rendered
super-eminent in dignity, in practical api>lication and utility ;
for l>y enabling the mind to apply the natural power thruugh
law, it conveys the gifts of Glod to man.
2S0 MICHAEL FARADAY.
A peculiar interest attaches to Faraday's attitude
towards tlie study of mat hematics. He who had
never had any schoohng beyond the common school
of his parish had not advanced beyond the simplest
algebra in his master}' over symbolic reasoning.
Several times in his ''Experimental Eesearches " he
deplores what he termed '' my imperfect mathe-
matical knowledc^e." Of Poisson's theory of rnao-netism
he said: ''I am quite untit to form a judgment."
f)r. Scoftern repeats a pleasantr}' of Faraday's having
on a certain occasion boasted that he had once in the
course of his life pertormed a mathematical operation
— when he turned the handle ot Babbage's calculating
machine. Certain it is that he went through the
whole of his rnagniticent researches without once
usino- even a sine or a cosine, or anythinu' more
recondite than the simple rule-of-three. He ex-
pressed the same kind of regret at his unfamiliarit}'
with the German lanL;uai=^e — " the lan^aiaoe of science
and knowledge," as he termed it in writing to Du Bois
Rej-niond — which prevented him from reading the
Ayorks of Professor *'Ohnjs." Xevertheless he valued
the mathematical powers of others, and counselled
Tyndall to work out his experimental results, " so that
the mathematicians niay be able to take it up." Yet
he never relaxed his preference for proceeding along
the lines of experimental investigation. His curious
phrase (p. 239) as to his picpie respecting mathematics
is very signiticant, as is also his note of jubilation in
his letter to Phillips (p. 117) at tinding that pure
experiment can successfull}' rival mathematics in
unravellino" the mysteries which had eluded the efforts
ON MATHEMATICS. 281
of Poisson and Araoo. Ho himself attributed to his
defective memory his want of hold upon symbolic
reasonmg. To Tyndall he wrote in 1851, when thank-
ing him for a copy of one of his scientific memoirs :- —
Such piipers aw your.s make me feel more than ever the loss
:)f memory I have sustained, for tliere is no reading them, or
at least retaining the argument, under such deficiency.
^Mathematical formuke more than anything require quick-
ness and surety in receiving and retaining the true value of
the symbols used ; and when one has to look back at every
moment to the beginning of a pajjcr, to see what H or A or B
mean, tliere is no making way. Still, though 1 cannot hokl
the whole train of reasoning in my mind at once, I am able
fully to a]ipreciate the value of the results you arrive at, and it
appears to me that they are exceedingly well established and
of very great conse(|uence. These elementary laws of action
are of so much consequence in the development of the nature
of a power which, like magnetism, is as yet new to us.
Aa^ain to Clerk Maxwell, in 1857, he wrote: —
There is one thing I Avould l.ie glad to ask you. When a
mathematician engaged in investigating physical actions and
results has arrived at his own conclusions, may they not be
exjiressed in common language as fully, clearly, and definitely
as in mathematical formuke^ If so, would it not be a great
boon to such as we to express them so — translating them out
of their hieroglyphics that w^e also might work upon them by
experiment 'I I think it must I)e so, because I have always
found that you could convey to me a jjerfectly clear idea of
your conclusions, which, though they may give me no full
understanding of the steps of youi- pi"ocess, gave me the results
neither above nor below the truth, and so clear in character
that I can think and work from them.
If this be possible, would it not be a good thing if mathe-
maticians, writing on these sultjects, were to give us their
2.S2 MICHAEL FARADAY.
results in this po])u]ar useful Avorkin.ij,- state as well as in that
^\■hich is tlieir own and proper to them 'I
The achievement of Faraday in finding for the
expression of electromagnetic laws means which,
though not symbohc, were simple, accurate, and in
advance of the mathematics of his time, has been
alhided to on page 217. Liebig, in his discourse on
" Induction and Deduction," refers to Faraday thus : —
I have heard mathematical ])hysicists dei)lore that Faraday's
records of his labours were ditticult to read and understand,
that they often resembled rather abstracts from a diary. But
the fault was theirs, not Faraday's. To physicists who Lave
approached i>hysics by the road of chemistry, Faraday's
memoirs sound like an admirably beautiful music.
Von Helmholtz, in his Faraday lecture of 1881,
has also touched on this aspect.
Now that the niatheiiiatical interpretation of Faraday s
conceptions regarding the nature of electric and magnetic
forces has been given by Clerk Maxwell, we see how great a
degree of exactness and precision was really hidden behind the
words which to Faraday's contemporaries appeared either
vague or obscure ; and it is in the highest degree astonishing
to see what a large number of general theorems, the methodical
deduction of which requires the highest powers of mathe-
matical analysis, he found by a kind of intuition, with the
security of instinct, without the help of a single mathematical
formula.
Two other passages from Von Hehnholtz are
worthy of being added : —
And now, with a quite wonderful sagacity and intellectual
lirecision, Faraday performed in his brain the work of a great
mathematician without using a single mathematical formula.
MAXWELL AND VON HELMHOLTZ. 283
He saw with his mind's eye that magnetised and dielectric
bodies ought to have a tendency to contract in the direction
of the lines of force, and to dilate in all directions perpen-
dicular to the former, and tliat by these systems of tensions
and pressures in tlie si)ace which surrounds electrified bodies,
magnets, or wires conducting electric currents, all the pheno-
mena of electrostatic, magnetic, electromagnetic attraction,
repulsion, and induction could be explained, without recurring
at all to forces acting directly at a distance. This was the
part of his path where so few could follow him ; perliaps a
Clerk Maxwell, a second man of the same power and in-
dependence of intellect, was needed to reconstruct in the
normal methods of science the great building the plan of
which Faraday had conceived in his mind, and attempted to
make visible to his contemporaries.
Nobody can deny that this neAv theory of electricity and
magnetism, originated l.»y Faraday and developed by Maxwell,
is in itself well consistent, in perfect and exact harmony with
all the known facts of experience, and does not contradict any
one of the general axioms of dynamics, which have been
hitherto considered as the fundamental truths of all natural
science, because they have been found valid, without any
exception, in all known processes of nature.
And, after dealing w^itli the phenomena discussed
by Faraday, Von Helmholtz adds these pregnant
words : —
Nevertheless, the fundamental conceptions by which
Faraday was led to these much-admired discoveries have
not received an equal amount of consideration. They were
very divergent from the trodden path of scientific theory, and
appeared rather startling to his contemporaries. His principal
aim was to express in his new conceptions only facts, with
the least jtossible use of hypothetical substances and forces.
This was really an advance in general scientific method,
destined to i)urify science from the last remnants of meta-
physics. Faraday was not the first, and not the only man,
:^<S4 MICHAEL FARADAY.
who liad worked in this direction, l.mt perhaps nobody else
at his time did it so radically.
Clerk Maxwell said of him :
The Avay in which Faraday made use of his lines of force
in co-ordinating the phenomena of electric induction shows
him to have been a mathematician of high order, and one
from whom the mathematicians of the future may derive
valuable and fertile methods.
It is fitting to include in this review of Faraday's
place in relation to the mathematical side of physics
some Avords of Lord Kelvin, taken from his preface
to the English edition of Hertz's "Electric Waves" : —
Faraday, with his curved lines af electric force, and his
dielectric efficiency of air and of lii[uid and solid insulators,
resuscitateel the idea of a medium through which, and not
only through which but b// which, forces of attraction or
repulsion, seemingly aeting at a distance, are transmitted.
The long struggle of the first half of the eighteenth century
was not merely on the question of a medium to serve for
gravific mechanism, but on the correctness of the Newtonian
law of gravitation as a matter of fact, however explained.
The corresponding controversy in the nineteenth century Avas
very short, and it soon became obvious that Faraday's idea
of the transmission of electric force by a medium not only did
not violate Coulomb's law of relation between force and
distance, but that, if real, it must give a thorough explanation
of that law. Nevertheless, after Faraday's discovery of the
different fe])ecitic inductive capacities of different insulators.
twenty years passed before it was generally accepted in Con-
tinental Europe. But before his death, in 1867, he had
succeeded in inspiring the rising generation of the scientific
world with something approaching to faith that electric force
is transmitted by a medium called ether, of which, as had
been believed by the whole scientific world for forty years,
Kelvin's appueciation. 285
light and radiant heat are transver.se viltratiniis. Faraday
lihnself did not rest with this theory of electricity alone.
The very last time I saw him at work at the Uoyal Institution
was in an underground cellar, which he had chosen for
freedom from disturbance, and he was arranging experiments
to test the time of propagation of magnetic force from an
electromagnet through a distance of many yards of air to a
fine steel needle, jiotishecl to reflect light ; but no result came
from those experiments. About the same time, or soon after,
certainly not long before the end of his working time, he was
engaged ([ believe at the Shot Tower, near AVaterloo Bridge,
on the Surrey side) in etforts to discover relations between
gravity and magnetism, which also led to no result.
Lord Kelvin, who was himself the first to perceive
that Faraday's ideas were not inconsistent with uiathe-
niatical expression, and to direct C'lerk Maxwell and
others to this view, had, in 1854, delighted the old
man b}^ bringing mathematical snpport to the con-
ception of lines of force. In 1857 he sent to Faraday
a cop3^ of one of his papers, and received in acknow-
ledgment a letter of warm encouragement, Avliich,
however, does not appear to have been preserved.
Lord Kelvin's rcpl}^ is its own best commentary : —
Such expressions from you would be more than a sufficient
reward for anything I could ever contemplate doing in science.
I feel strongly how little I have done to deserve them, but they
will encourage me with a stronger motive than I have over
had before to go on endeavouring to see in the direction you
have }iointed, wliich I long ago learned to believe is the
direction in Avliicli we must look for a dcejicr insight into
nature.
CHAPTEE YllL
RELIGIOUS VIEAVS.
The name of Glasites or Sandemanians is given to
a small sect of Christians ■which separated from the
Scottish Presbyterian Church about 17o0 under
the leadership of the Rev. John Glas. Most of the
congregations which sprang up in England Avere
formed in consequence of the dissemination of the
writings and b}^ the preaching of Robert Sandeman,
son-in-hiw and successor of Glas. Hence the doul.'le
name. The Sandemanian Church in London Avas
constituted about 1760. It still has a chapel in
BarnsbuiT, though the sect as a Avhole — never
numerous — has dwindled to a small remnant.* The
religious census of 1S51 showed but six congregations
in England and six in Scotland. As it never was a
prosel3'tising bodj', it is probable that it has diminished
since that date. John Glas Avas deposed m 1 72S
by the Presbyterian Courts from his position as
minister in the Scottish Church, because he taught
■^■" Faraday's nqihow, Frank Hariiard, stated m 1S71 Uiai the L^jiidon
congregation included amongst its members not more than twenty men,
mostly quite x^oor, only seven or eight of them being masters of their
own businesses, and that Faraday was fur sume time the wealthiest
man of the fraternity.
THE SANDEMANIAN CREED. 287
that the Church should be governed only by the
doctrmes of Christ and His apostles, and not be
subject to any League or Covenant. He held that
the formal establishment by any nation of a pro-
fessed religion was the subversion of primitive
Christianity ; that Christ did not come to establish
any worldly authority, but to give a hope of eternal
life to His people Avhom He should choose of His own
sovereign will ; that " the Bible," and it alone, with
nothing added to it nor taken away from it by man,
was the sole and sufficient guide for each individual,
at all times and in all circumstances; that faith in
the divinity and work of Christ is the gift of God,
and that the evidence of this faith is obedience to the
commandment of Christ.
The tenets of Glas are somewhat obscure and
couched in mystical language. They prescribe a
spiritual union which binds its members into one
body as a Church without its being represented
by any corresponding outward ecclesiastical polity.
He died in 1773. Sandeman, who spent most of
his life in preaching these doctrines, died about the
same time in New England. He caused to be
inscribed on his tomb that "he boldly contended
for the ancient faith that the bare death of Jesus
Christ, without a deed or thought on the part
of man, is sufficient to present the chief of sinners
spotless before God."
The Sandemanians try — so far as modern con-
ditions permit — to live up to the practice of the
Christian Church as it was in the time of the
Apostles. At their chapel they " broke bread "
2.S8 MICHAEL FARADAY.
every Lord's day in the forenoon, making this a
common meal between the morning and afternoon
services, and taking their pLaces by casting lots.
And weekly, at their simple celebration of the Lord's
Supper at the close of the afternoon service, before
partaking, they collect money for the support of the
poor and for expenses. In some places thc}^ dined
together at one another's houses instead of at the
chapel. " They esteem the lot as a sacred thing.
The washing of the feet is also retained : not, it would
seem, on any special occasion, but the ablution is
performed ' whenever it can be an act of kindness to
a brother to do so.' Another peculiar! ty of this
religious body is their objection to second marriages." *
]\Iembers are received into the Church on the con-
fession of sin and profession of faith made pubhcly at
one of the afternoon services. In admitting a new
member they give the kiss of charity. Thc}^ deem it
"wrong to save up money ; '' the Lord Avill provide "
being an essential item of faith. Traces of this curious
fatalism ma}^ be found in one of Faraday's letters to
his Avife (p. 52). He seems always to have spent his
surplus income on charity. The Sandemanians have
neither ordained ministers nor paid preachers. In
each concrre^ation, however, there are chosen elders
(presbyters or bishops), of Avhom there nuist always be
a plurality, and of whom two at least must be present
at every act of discipline. The elders take it in turns
to preside at the worship, and are elected b}^ the
unanimous choice of the conoreo^ation. The sole
'"" C. M. Davios : " Unorthodox London," page 281.
A PRIMITIVE CHURCH. 2<S9
qnalitication for this office, which is unpaid, is that
earnestness of purpose and sincerity ot* Ufe which
would have been required iu Apostolic times for the
office of bishop or presbyter. No difference of opinion
is tolerated, but is met by excommunication, which
amongst famihes so connected by marriage produces
much unhappiness, since they hold to the Apostle's
injunction, " With such an one, no, not to eat."
The foregoing summary is needed to enable the
reader to comprehend the rehitionship of Farada}^
to this body. His father and grandfather had be-
longed to this sect. In 17G3 there was a congregation
at Kirkby Stephen (the home of Faraday's mother)
numbering about thirty persons; and there appears
to have been a chapel — now used as a barn — in
Clapham. A strong religious feeling had been
dominant in the Faraday family through the preced-
ing generation. James Faraday, on his removal to
London, there joined the Sandemanian congregation,
which at that time met in a small chapel in St. Pauls
AUe}^, Barbican, since pulled down. It had, when
founded in 1762, held its first meetina^s in the hall of the
Glovers' Company, and later in Bull and Mouth Street,
till 1778. James Faraday's wife, mother of Michael
Faraday, never formally joined the Sandemanian
Churcli, though a regular attendant of the congrega-
tion. Michael Faraday was from a boy brought up
in the practice of attending this simple worship, and
in the atmosphere of this primitive religious faith.
Doubtless such surroundings exercised a moulding
influence on his mind and character. The attitude
of abstinence from attempts to proselytise, on the part
T
290 MICHAEL FAllADAV.
ot the church, tiiids its reflex m Faraday's habitual
reticence, towards all save otily the most intimate of
friends, on matters of religious faith. " Xever once,"
says Professor Tyndall, " during an intimacy of fifteen
years, did he mention religion to me, save "when I
drew him on to the subject. He then spoke to me
without hesitation or reluctance : not with any
apparent desire to 'improve the occasion,' but to give
me such information as I sought. He believed the
human heart to be swayed by a power to which
science or logic opened no approach ; and right or
wrong, this faith, held in perfect tolerance of the faiths
of others, strengthened and beautified his life."
Of his spiritual history down to the time of his
marriao-e very little is known, for he made no earher
profession of faith. It is not to be supposed that he
Avho Avas so scrupulous of truth, so single-minded in
ever}' relation of life, would accept the religious belief
of his fathers without satisfying his conscience as to
the rio'htness of its claims. Yet none of his letters or
writings of that p)eriod shoAv any trace* of that stress
of soul through which at one time or another every
■ A letter from hi^ nephew, Frank Barnard, to Dr. Gladstone says :
" I Ijulieve that in his younger days he liad his period of hesitation, of
questioning in that great argmnent. I have heai'd that, so alive was
he to the necessity of investigating anything that seemed important,
he ■^'isited Joanna Southeote. perhaps to learn what that woman's pre-
tensions were : I think he was a mere lad at that time. But this
period once pi^^sed, he questii;tned no more, for the more he saw that
Xature was mighty, the more he felt that God was mightier : and to
any cavillings upon the doubts of Colenso or the reality of the Mosaic
cosmogony, I beheve he would simply have replied in the apostle's
words : ' Is anything too hard fur Cxod !' ' . . .
*' I once heard him say fi'om the pulpit, ' I hojie none of my heai'ers
will in these matters listen to the thing called philosophy.' "
HIS PROFESSION OF FAITH. 291
sincere and earnest seeker after truth must pass before
he iintls anchoraii^e. Certain it is that he chmo- with
warn"! attachment to the httle solf-containecl sect
amono-st whom he had been brou^'ht up. Its influence,
though contracting his activities by precluding all
Christian communion or effort outside their circle,
and cuttini;' him oft' from so nmcli that other Christian
bodies hold good, fenced him effectually from dreams
of worldliness, and furnished him with that very
detachment which was most essential to his scientitic
pursuits. One month after his marriage he made
his confession of sin and profession of faith before the
Sandemanian Church. It was an act of humility the
more striking in that it w^as done without any con-
sultation with his wife, to whom he was so closely
attached, and who Avas already a member of the
congregation. When she asked him why he had not
told her what he was about to do, he replied : " That
is between me and my God."
In 1844 he wrote to Lady Lovelace as follows : —
" You speak of religion, and hero you will be
sadly disappointed in me. You will perhaps re-
member that I guessed, and not very far aside, your
tendency in this respect. Your confldence in me
claims in return mine to you, which indeed I have
no hesitation in giving on titting occasions, but
tliese I think are very few, for in my mind re-
ligious conversation is generally in vain. There Is
no philosopJty in ■my Teli(ji.on. I am of a very
small and despised sect of Christians, known, if
known at all, as Sandemanians, and our hope is
founded on the faith that is in Christ. But thourfi
292 MICHAEL FARADAY.
the natural works of God can never by any possibility
corae in contradiction with the higher tilings that
belono; to our future existence, and nmst with
everything concerning Him ever glorify Him, stih
I do not think it at all necessary to tie the study
of tlie natural sciences and religion together, and,
in my intercourse with my fellow crea.tures, tha.t
whicli is religious and that Avhich is philosophical
have ever been two distinct things."
His own views were stated by himself at the
connnencemont of a lecture on Mental Education
in 1<S54:—
High aa man is jjLiced above the creatures around him,
there is a higher and far more exalted iiosition within his
view ; nnd the ways are infinite in whicli he occupies liis
thoughts about the fears, ur hopes, or ex])ectations of a future
life. I believe that the truth of that future cannot lie brought
to his knowledge by any exertion of his mental powers, how-
ever exalted they may be ; tliat it is made known to him by
other teaching than his own, and is received through simple
belief of the testimony given. Let no one suppose for a
moment that the self-education I am aljout to connnend, in
respect of the things of this life, extends to any considerations
of the hope set before us, as if man by reasoning could find
out (iod. It would be im^n'oper here to enter upon this
subject further than to claim an absolute distinction between
religious and ordinary belief. I shall be reproached with the
weakness of refusing to a]iply those mental operations which
I think good in respect of high things to the very highest.
I am content to bear the reproach.
One of his friends wrote : " When he entered
the meeting-house he left his science behind, and
he would listen to the prayer and exhortation of
the most illiterate brother of his sect with an
A8 ELDER AND PREACHER. 298
attoition Avliich sliowcd how ho loved the word of
truth, from whomsoever it caine."
" The most remarkable event/' says Dr. Eonce
Jones, " of his life in 1840 was his election as an
elder of the Sandemanian CUiurch. During that
period when in London he preached on alternate
Sundays." This was not an entirely new duty, for
he had been occasionally called upon by the elders,
from the date of his admission in 1821, to exhort
the brethren at the Aveck-day evening meetings, or
to read the Scriptures in the congregation. Bence
Jones says that, though no one could lecture like
Faraday, many might preach with inoro effect.
The eager and vivacious manner of the lecture-
room was exchanged for a devout earnestness that
was in complete contrast. His addresses have been
described as a patchwork of texts cited rapidly
from the Old and New Testaments ; and they were
always extempore, though he prepared careful notes
on a piece of card beforehand. . Of these, samples
are given in Bence Jones's " Life and Letters." His
first discourse as an elder was on Matt. xi. 28-30,
dilating on Christ's character and example. " Learn
of Me." The ground of humility of Christians must
be the infinite distance between them and their
Pattern. He quoted 1 John ii. G ; 1 Peter ii. 21 ;
Phil. hi. 17; 1 Cor. xi. 1: and I Cor. xiv. 1.
An exceedingly vivid view of Faraday as elder
of the Church was given in 1886* by the late Mr.
C. C. Walker, himself at one time a member of
'■ ^[auchcHter Oiicirdijin. Novemhcr 27.
204 MICHAET. FAltADAY.
tlio SaiKlciiianiun C(^ngroi^"ation in Ijoiidoii ; a con-
gvcgatioii, moreover, ■wliicli included several ])ersons
of distinction — Cornelius Yarley, the cn_^"raver, and
Geori^e Barnard, the Avater-coloiu' painter.
At [''jiradiiy s cliaiiel there was a I'rcsidin,!;' elder, suiipiirled
l>y the rest of the elders on two rows of seats elevated neross
the end of the chapel, one row above the otlier. The ground
lloor Avas filled with the old-fashioned hi^h pews, and tliere
was a gallery above on both sides, also with pews. Fara-
day sat in a ])ew on the ,i;Tiinml lloor, about the middle.
There was a large table on the IhKtr nf llic chapel in front
of the elders' seats. The presi<bng elder usually iireacJiL'd.
Such was the jilacc baradny worshipped in, situated at the
cud of a nairow dirty coiii-t, surrounded by S([Ualid houses
of the poorest o\' the })Our, and so little knoAvn tliat altliough
1 kuuw (.'Vd'y street, lane and alley of the whole district,
anel this alley itself, at the bottom of which the chapel was,
I never knew of the existence of the mectingdiouse till I
learned about tliirty-fi ve years ago tliat there was a chapel there
to which the worhi-rcnowned Fara(Lay not only went, but where
he preached. This led me to make a search, and to my
great delight, 1 found it, though with some difliculty. Al-
though the ueigljbourhood was uncleanly, not so was the
interior of tlje chapel, nor the dining room, with its tables
and forms, all of which were s])otless.
Faraday's father was a blacksmith, and worsliip]f((l here.
Ife brought up Ins family religiously, and Faraday from
his earliest days attended the clia[)el. Here he met Miss
Pjarnanl, his future wife. ^Ir. barnaid was a rcspeelablc
'' working silversmith," as manufacturing silvci>nutlis were
then called, to distinguish them from the sliopkeei)ers who
then, as now, called themselves "silversmiths," though fre-
ipiently making none of the goods they sell. His manufactory
was for a time at Amen Court, Paternoster Row ; afterwards
it was removed to a large building ei'ccted by the firm at
7\ugel (Street, near the General Post Ofhce, and the business
has since been carried on l»y the sons and grandsons.
RELIGIOUS SERVICE. 295
Mr. Barnard and his family worshipped at the Sande-
manian Chapel. To this chapel Faraday walked every
Simdny morning from his earliest days ; he never kept a
carriage, and on religious principles' Avould not hire a cab
or omnibus on the Lord's day.^"
The service commenced at eleven in the morning and
lasted till about ouej after which the members — " brothers
and sisters," as they called each other — liad their midday
meal "in common" in the room attached to the chapel,
which has already been referred to. The afternoon worship
usually ended about five o'clock, after partaking of the Lord's
Supper. The services were very much like those of the
Congrega.tionalists, and consisted of extempore prayers, hynms,
reading the Scripture, and a sermon, usually by the presiding
elder. Faraday had been an elder for a great many years,
and for a consideral.>le time was the presiding elder, and
conseijuently preached ; but during this time reliiKjuished
his office. There was one peculiarity in the service ; the
Scriptures were not read by the presiding elder, but he
called on one of the members to read ; a.nd when Faraday
was there — which he always was when in London— the pre-
siding elder named " Brother Michael Faraday," who then
left his pew, passing along the aisle, out of the chapel, up
the stairs at the back, and reappeared behind the presiding
elder's seat, who had already opened the large BilJe in
front of him, and ])ointed out the chapter to be read. It
was one of the richest treats that it has been my good
fortune to enjoy to hear Faraday read the Bible. The reader
was quite unaware what he Avas to read until it was selected
and when one chapter of the Old Testament was finished
another would be given, probably from the New Testament.
Usually three chapters were read, and sometimes four, in
succession ; but if it had been half a dozen there would
have been no weariness, for the perfection of the reading,
with its clearness of pronunciation, its judicious emphasis,
[* This is not altogether accurate. Certainly in his later Ufo
Faraday used to hire a cab to take him and Mrs. Faraday to the
chap(-.a." fS. P. T.]
296 MICHAEL FARADAY.
the rich musical voice, and the perfect chanii of the reader,
Avith his natural reverence, made it a delight to listen. I have
heard most of those who are considered our best readers
in church and chapel, but liave never heard a reader that
I considered equal to Faraday.
At this distance of time his tones are always in my ears.
I was told by members of the chapel tliat he was most
assiduous in visitin;^^ the poorer brethren and sisters at their
own homes, comforting them in their sorrows and afflictions,
and assisting them from his own purse. Indeed, they said, he
was continually pressed to be the guest of the high and noble
(which we may well believe), but he would, if possible, decline,
preferring to visit some poor sister in trouble, assist her, take
a cup of tea with her, read the Biljleand pray. Though so full
of religion, he was never obtrusive with it ; it was too sacred a
thing.
Tyndall has preserved another vivid reminiscence
of Faraday's inner life, wdiicli he wTote down after one
of the earliest dinners which he had in the Royal
Institution.
" At two o'clock he came down for me. He, his
niece, and myself formed the party. ' I never give
dinners,' he said ; ' I don't knoAv how to give dinners ;
and I never dine out. But I should not like my
friends to attribute this to a wrong cause. I act
thus for the sake of securing time for Avork, and not
through religious motives as some imagine.' He said
grace. I am almost ashamed to call his pra3^er a
saying ' of grace. In the language of Scripture, it
might be described as the petition of a son into
whose heart God had sent the Spirit of His Son, and
who with absolute trust asked a blessing from his
Father. We dined on roast beef, Yorkshire pudding,
C5
ELDEUSHU' INTERRUPTED. 297
and potatoes, drank sherry, talked of research and its
requirements, and of his habit of keeping himself free
from the distractions of society. He Avas bright and
joyful — boylike, in fact, though he is now sixty-two.
"His work excites admiration, but contact with hiui
warnjs and elevates the heart. Here, surely, is a
strong man. I love strcjigth, but let me not forget
the example of its union with modesty, tenderness,
and sweetness, in the character of Faraday."
There is a story told by the Abbe Moigno that
one day at Faraday s request he introduced him to
Cardinal Wiseman. In the frank interview which
followed, the Cardinal did not hesitate to ask Farada}^
whether, in Ins deepest conviction, he believed all the
Church of Christ, holy, catholic, and apostolic, was
shut up in the little sect in Avhich he was ofHcially an
elder. "Oh, no!" was Faraday's reply; "but I do
believe from the bottom of my soul that Chiist is
with us."
The course of Faraday's eldership was, however,
interrupted, It was expected of an elder that he
should attend ever}^ Sunday. One Sunday he was
absent. When it was discovered that his absence was
due to his having- been " commanded " to dine with
o
the C^'Jeen at Windsor, and that so far from expressing
penitence, he was prepared to defend his action, his
office became vacant. He was even cut off' from
ordinary membership. Nevertheless, he continued for
years to attend the meetings just as before. He
would even return from the provincial meetings of
the British Association to London for the Sunday, so
as not to be absent. In 1800 he Avas received back as
29s MICHAEL FARADAY.
iLii elder, which office lie held agam for about three
years and a half, and finally resigned it in 1864.
It is doubtful whether Faraday ever attempted to
form any connected ideas as to the nature or iriothod
of operation of the Divine government of the physical
world, in which he had such a whole-souled belief.
Newton has left us such an attempt. Kant in his
own way has put forward another. So did Herschol ;
and so in our time have the authors of "The Unseen
Universe." To Faraday all such "natural theology"
would have seemed vain and aindcss. It was no part
of the lecturer on natural philosophy to speculate as
to final causes behind the physical laws with which
he dealt. Nor, on the other hand, was it the slightest
use to the Christian to inquire in what way Clod ruled
the universe : it Avas enough that He did rule it.
Faraday's mental (jrganisation, which made it
possible for him to erect an absolute barrier between
his science and his religion, was an unusual one. The
human njind is seldom built in such rigid compart-
ments that a man whose whole life is spent in
analysing, testing, and weighing truths in one dejjart-
ment of knoAvledge, can cut himself off from applying
the same testing and inquiring processes in another
department. The founder of the sect hud taught them
that the Bible alone, with nothing added to it or taken
away from it by man, was the only and sufficient guide
for the soul. Apparently Faraday never admitted
the possibility of human flaw in the printing, editing,
translation, collation, or construction of the Bible.
He apparently never even desired to know how it
compared with the oldest manuscripts, or what was
RELIGIOX AND SCIENCE. 299
the evidence for the authenticity oF the vai-ions
versions. Having once accepted the views of his sect
as to the absohite inspiration of the EngUsh Bible as
a whole, he permitted no subsequent question to
be raised as to its literal authority. Tyndall once
described this attitude of mind in his own trenchant
way by saying that Avhen Faraday opened the door of
his oratory he closed tliat of his laboratory. The
saying may seem hard, but it is essentially true. To
few indeed is such a limitation of character possible :
possibly it may be unique. We may reverence the
frank single-minded simplicity of soul which dwelt in
Farada}^ and may yet hold that, whatever limitation
was right for him, others would do wrong if they
refused to bring the powers of the mind — God-given
as they believe — to bear upon the discovery of truth
in the region of Biblical research. Yet may none
of them dream of surpassing in transparent honesty
of soul, in genuine Christian humility, in the virtues
of kindness, earnestness, and sympathetic devotion,
the great and good man who denied himself that
freedom.
INDEX
AlDbott, Benjamiii, 7, H, 97, 227;
letters to, 7, 0, lo, 22, 20, 20, 41,
44, 228
Acoustical researches, loC)
Action at a distance uuthinkal^le,
12,S, 153, 157, 216
Admiralty, Scientilic adyiser to
the, C8
_iEther, the. Speculations ui:>on ,
193, 213
Air}', Sir Geoi'ge, Dispnte with,
269
Aloofness from sciontihc organisa-
tions, 261
Ampere, Andrtie Maiie, Meeting
with, 19; his researches, 80, 82,
85, 105, 126
Analyst, Faraday' s professional
work as, 51, 61, "63, 274
Anderson, Sergeant, engaged as
assistant, 96 ; his imj^licit obedi-
ence, 97, 242
Andrews, Professor T., Letter to,
273
Apparatus, Simplicity of, 239
Arago, F., Meeting with, 34, 238 ;
his notations, 106, 116, 118; his
philosophical reserve, 107
Armstrong, Lord, on electrification
of steam, 170
Artists amongst acquaintances, 246
Astley's Theatre, 51
Athenfeum Club, 59
Atmospheric magnetism, 206, 209,
210
Atoms or centres of force, 241
Autobiographical notes, 8, 17, 50,
58, 70, 71, 73, 76, 223, 243
B.
Babbagc, Charles, 107, 116, 202
Barnard, Edward, 4l)
, Frank, 250, 286
, George, 46, 51, 71, 89, 224,
246, 294
— , Miss Jane, 46, 259
, Sarah (Mrs. Faraday),
46, 294
Becker, Dr., Letter to, 244
Beuce Jones's " Life and Letters
of Faraday," 7, 26, 40, 43, 48,
57, 58, 78, 108, 199, 226, 231, 293
Benzol, Discovery of, 94, 101
Bidwell, S., magnetic action of
light, 184
Biographies of Faraday (see Pee-
FACt:)
Boltzmann : on crystalline dielec-
trics, . 166 ; on the doctrines of
Faraday and Maxwell, 216
Bookbinding, 5, 6, 17, 249
Bookselling, 5, 17, 26, 31
Books by Faraday: — "On the
Means of Obtaining Know-
ledge," 41 ; "Chemical Manipu-
lations," 101, 233; "On Alleged
Decline of Science in England"
(editor), 110; "Experimental
Kesearches in Electricity and
Magnetism," 102; "Experi-
mental Researches in Cheniistry
and Physics," 76; " Un the
Prevention of Dry Hot in Tim-
ber," 149 ; " Chemistry of a
Candle," 234; "The Forces of
Nature," 234
.302
MICHAEL FARADAY.
Buots, a home-made pair of, 240
Braude, W. F., Prof., ;J9, ;')?
Breakdown in health, 170, 1!I9,
222, 259
British Association, GI, 224, 204,
268, 207
Browiiinn;, Mrs. E. B,, denounces
Faraday, 2ol
Burdett-Coutts, Baronnss, Letter
to, 240
C.
Cards, L'^se of, to assist memory, 7,
239
Charge, eloetric, (^uei-y as to seat
of, 1.'.4
, The nature of an electric,
152
Charitable gifts, 215, 29fl
Chemical researches, 45, 82, S7 ;
analysis of caustic lime, 7G ; new
chlorine componnds, cS7 ; li(iue-
fiictirm of chlorine, 9'i ; discovery
of henzol, 94; suljiho-naphthtilic
acid, 10(1
Clieiiiistry, How to cxiuiiine in,
277
Children and Faraday, 2IJ3, 235
Chlorine, Liquefaction of, oo, 91
Christmas lectures, 33, 37, 01, 101,
233, 234, 235, 258
City Philosophical Societ}^, 14, 10,
40, 41, 230
Clerk Maxwell, J. : article on
Faraday, 135; theoiy of con-
iluctiun, 155 ; electromagnetic
theory of light, 199 : on Fara-
day's conception of electric
action, 217 ; letter to, on mathe-
matics, 281
Closing daj's of Faraday's life, 259
Coinage of new words, 116, 143,
144, 103, 188, 205
Commonplace hooks, 40, ^9
Conduction, Theory of, 155
Conservation of energy, 167, 219
Contact theory of cells, 168
Continent, Visits to, 16, 17, 74,
224
Controversy, Detestation of, 268
Convolutions of the forces of
nature, 167, 172, 269, 270
Copper disc experiment, 113
Criticism, Uses of, 14, 231, 240,
269
Crosse, Mrs. A., Keniiniscenccs of,
233, 215, 270
Crystallisation in relation to electric
properties, 166, 167
Crystals in the magnetic field, 200,
202
Current, Conception of a, 146, 163
Cutting the magnetic lines, 134,
213
Crookes, Sir W., Advice to, 267
D.
Dalton, John, 65, 226
Dance, Mr., gives Faraday tickets,
8 ; message to, 30
Daniell, Prof. J. F., 61
Davy, Sir Humphry : lectures of,
8, 36, 227 ; note to Faraday, II ;
engages Faraday, 12 ; travels
abroad, 17; his aristocratic lean-
ings, 25 ; researches on electric
arc, 37 ; invention of safety
lamp, 37, 42, 209 ; writes to
Faraday, 41. 45 ; misunderstand-
ing with, 50 ; his jealousy of
Faraday, oG, 59 ; his electro-
magnetic discovery, 80 ; and the
liquefaction of chlorine, 93
Davy-Faraday laboratory, The, 36
Do ia Rive, Auguste, 29, 6f;, 105,
237; letters to, 29, 185
— , Gustavo, 20, 28,
110, 141 ; letters to, 83, 85, 91,
207, 207
De la Rue, Warren: his lecture,
39; his eclipse photogiTiphs, 219
Diamagnetic, A, 179
polarity, 192, 210
Diamagnetism, Discovery of, 180
Dielectric medium, 153, 159, 163
Diploma-book, 271
Discharge, electric, Forms of, 137,
102
, Dark, 102
Discoveries, Value of, 63, 224, 248
Disijlacement currents, 166
Doctrine of conservation of energy,
167, 219
of correlation of forces, 172,
269, 270
of electrons, 148
Domestic affairs, 49, 69, 244, 257
Doubtful knowledge. Aversion for,
46, 92 _
Dry rot in timber, 149
INDEX.
803
Dumas: Reminiscences "by, 20, o9,
240 ; and Araii-o's copper, 106 ;
discover}' of oxalamide, I'iT
E.
Eddy-currents, Eil'ccts due to, 107,
ly'l, 2(14
Education, Views on, 278
Eel, The electric, 167
Electric light for lighthouses, 21S,
269
Electrical machine, Faraday's
own, 6
— — , The "new," 121
Electrocheraicallaws, 141, 147
Electrodes, 143
Electrolysis, 143
Electrolytes, 143
Eiectromagnetic rotations discov-
ered, ol, 83. 87
Eleoti'umaguctism, Fouudatious of,
77
Electrons, Doctrine of, 148
Electrotouic state, 116, ]26, 160,
21o
Elocution, Lessons in, 43, 230
Enthusiasm, 15, 89, 225, 240
Ether, The (ire TEther)
Evolution of electricity frrun mag-
netism, 108, 114
Examinations in chemistry, 277
Experiment, Love of, 117, 230, 276
the touchstone of hj'pothesis,
221
■ rtr.si'.s mathematics, 117, 239,
280
Exj)talmental researches in elec-
tiicity and magnetism : the tirst
series, 113 ; the last series, 216 ;
Clerk Maxwell on, 218
Fxpertwork, 51, 61, 63, 274
Explosions iu the laboratory, 94
F.
Faraday, James, 1, 2, 224
~, Michael : born, 1 ; scltooling
of, 2 ; goes as errand boy, 3 :
apiirenticed as bookbinder and
stationer, 5 ; journeyman book-
binder, 9 ; attends Tatum's
lectures, 6 ; attends Sir H,
Davy's lectures, 8 ; acts as
Davy's amanuensis, 10 ; engaged
at Koyal Institution, 12; his
foreign tour with Davy, 16 !
visits Paris, 18; visits Florence,
21 ; visits Geneva, 22, 28 ; returns
to Royal Institution, 34 ; lectures
at City Philosophical Society,
40, 43 ; loyalty to Davy, 42, 5U,
269 ; begins original work, 46 ;
falls in love, 46 ; his poem to
Miss Barnard, 46 ; his wedding,
49 ; made . superintendent of
laboratory, 49, 98 ; discovers
electromagnetic rotations, 51 ;
elected F.R.S., 59 ; made D.C.L.
of Oxford, 65 ; awarded Cojolej^
Medal, 69 ; declines professor-
ship in London Univer.sity, 66 ;
receives a pension in Civil List,
72 ; appointed adviser to Trinity
House, 67 ; axjpointed elder in
Sandemanian church, 293 ; dis-
covers magneto- electric induc-
tion, 112, 115; discovers mag-
neto-riptic rotation, 176 ; discovers
diamagnetism, 186 ; readmitted
to Sandemanian church, 297 ;
exposes spiritualistic jthenomcna,
250 ; declines Presidency of
Royal Society, 255 ; declines
presidency of Royal Institution,
255 : resigns professorship at
Royal Institution, 259 ; resigns
advisership to Trinity House,
259; resigns eUlershii)in Sande-
manian church, 259 ; decease
and funeral, 260
-, Robert, 1, 2, 6, 249, 250
, Sarah (Mrs. Faraday), 49, 50,
51, 223, 225, 255, 257, 291 ; letters
to, 47, 48, 52, 53, 256
Faraday's father, 1, 2, 224, 289
^— mother, 1, 2, 12, 17, 22, 33,
41, 69, 289
Fatalism, 52, 288
Fees for professional work, 51, 61,
244, 274
Field, The magnetic; first use of
this term, 188
Fishes, electrica-l, Researches rm,
2U, 139, 167
Fluids, Alleged electric and mag-
netic, 212, 216, 218
Foreign travel, 16, 17, 74, 224
Fox, Caroline, Reroinisccuces of,
235
Frasef^s Magaz-uic and Faraday's
pension, 72
304
MICHAEL FARADAV.
Fresnel's amiouucement, lO.i
Friday evenings at the Koval
Institution, 33, 60, 100, 101, UW
166, 170, 192, 203, 21'J, 220, 22').
232, 236, 259
Fuller, John, founds the FuUeriau
professorships, 36
Funeral, 260
G.
Gases. Liquefaction of. '>o. 91, 171
, Matjuetic properties of. 204,
20S
Gassiot, J. P., Reminiscences hv.
German lauc;uage. Views on the,
2S0
Gladstone, Dr. J. Hall. 60, 290
Glass, Researches on, 95
GlaSsiteS (.s-fC SiNDKlIANIiNS")
Gold, Optical properties of, 219
Gra-\T.tj in relation to electricity,
204. "220. 2So
— — , Speculations as to, 195, 203
Grove, SirWm., 263, 269
Gymnotus, 167
Incandescent electric lamps, 199
Income, 68, 215
Indignation against wrong, 227
Induced currents, 114
Induction (electromagnetic), Dis-
coverj' of, 114
(electrostatic), or influence,
153
. Aleaniug of the term, 119
Inductive capacity, 159
Influence {.fcf Induction)
Inner conflicts. 226, 290
Iodine, Davy's experiments on, 19,
21.27
Ions. (_)rigin of term, 144, 145
J.
Jentiu, "Wm.. observes spark at
break, 150, 243
-Tones (.svr Bence Jon'ks)
Journals of foreign travel, IS, 224
Juvenile lectures at Roval Institu-
tion, 33, 37, 61, 101, 233, 231,
235, 25S
H.
Hachette. Letter to, 266
Hampton Court, House at. 257,
25y
Hare, R., Letter to, 269
Harris, Sir \V. Snow, 64, 26!)
Heat, Effect of. on magnetism.
208
Heavv-glass, 100, 176
Helmholtz, Prof. H. von, 282, 283
Henry, Professor Joseph, Reminis-
cence bv. 241
Herschel,' Sir John, 57, O^, 107,
116, 131, 262, 297
Home life, 49, 69, 223. 244. 257
Honours awarded to Faradav, 69,
199, 244. 255. 271
, scientific. Views on. 271
Hyjiotheses, Free use of. 221, 241
I.
Ice a non-conductor. 140
, Regelation of, 219
Identity uf electricity from differ-
ent sources, 137
Imagination, Use of the, 160, 227,
276
Kclile. Rev. J., and the hodge-
pndgc of philosophers, 66
Kelvin, Lord : theory of electro-
motive forces, 148 ; on theory of
magnetic penneability in a?olo-
tropic media, 201 ; on Faraday's
views of electricity, 281; letter
from, 285
Ken-, Dr. Johu : electro-optic dis-
covery, 173; m^agueto- optic dis-
covery, 182
Kindliness, 226
Kniglitliood no lionour, 273
Kuudt, Aug., magueto-optic dis-
covery, 1S2
L.
Laboratories at Albemarle Street.
36, 51. 66, 80, 84, 96
Lateral effects of cuiTeut, 151. 165,
170
Lectures at Royal Institution :
Davy's, 8. 36; Faradav's tii-st,
227;" Juvenile. 33, 37, '61, 101,
233, 234, 235, 258 ; afternoon,
37, 166
, Friday night discourses, 33,
INDEX.
805
00, 100. 101, 149, 166, 170, 192,
20;j, 219, -I'lO, '225, 232, 236, 2o9
Luctures at the Loudou Iii.'stitution
101
at the British Associatiou,
201-
— — - at St. George's Hospital, 166
at Woolwich, GO, 101
•Lecturiug, Views about, 16, 226,
232, 238
Letters from Faraday to : Ahhott,
B., 7, 9, 15, 22, 25, 26, 41, 44,
228 ; Andrews, T., 273 ; Baruard,
Miss Sarah, 47, 48 ; Becker, Dr.,
244; Burdett-Coutts, Baroness,
240; Davy, Sir H., 10; De la
Rive, A., 29, 185; De la Rive,
G., 83, 85, 91, 207, 267 ; Deacon,
Mrs., 253 ; Faraday, Mrs., 52,
53, 256; Grove, Sir Wm., 263;
Hare, R., 269; Lovelace, Lady,
291; Matteucci, Prof. C, 253,
262, 267 ; Melbourne, Lord, 71 ;
Moore, Miss, 207 ; Mun-ay, Mr.
John, 234; Paris, Dr. J. A., 10,
93; Percy, Dr. J. 253; Phillips,
R., 61, 109, 114, 194, 270, 277;
Riebau, G., 30; Royet, Dr. P.,
99 ; Schonbeiu, Professor, 206 ;
252 ; the Deputy- Master of
Trinitv House, 67 ; Tyndall,
Prof. J., 210, 204, 268, 277, 278,
280 ; Whewell, Rev. W., 145 ;
Young, Dr. T., 97
to Faraday : From Sir H.
Davy, 44, 45 ; from Baron
Liebig, 225 ; from Sir W. Thom-
son (Lord Kelvin), 285; from
Rev. W. Whewell, 116, 144, 145,
163, 205
Liebig, J. von, Reminiscences by,
224, 282
Light, Action of magnetism on,
176
, Electromagnetic theory of,
197, 199, 213
Lighthouses, Scientific work for,
67, 199, 218, 259
Lmes of force, 113, 133, 195, 208,
211, 213, 285; vibrations of, 195
Liquefaction of gases, 55, 91, 171
Loudou L^niversity {■•ice Uni-
veesitt)
Love of children, 233, 235
, Poetical diatribe against, and
recantation, 40, 47
Lovelace, Lady, Letter to, 291
Love-letters of Faraday, 47, 48, 52,
53, 256
M.
Magaecrystallic forces, 201
Magnetic lines, 113, 133, 195, 213,
214
Magnetisation by ligiit, 183
of light, 176
M;iguetism and cold, 167
■ of gases, 204
■ of rotation, Alleged, 106, 121
Magneto-electric discovery, 95, 112
induction, 115
— ^ light, 120, 130, 218, 250
machines, 122, 125, 126, 218,
259
Magneto -optical researches, 176,
182, 220
Magrath, E., 7, 14, 60, 231
Marcet, Mrs., Conversations on
Chemistry, 6
Masquerier teaches Faraday to
draw, 8
Mathematics vcraus experiment,
117, 239, 280
, Faraday's views on, 280, 281
and Faraday's methods, 217,
282
Matteucci, C, Letters to, 253, 262,
267
Maxwell {see Clkek Maxwell)
Mayo, Herbert, Impromptu by,
117
Meat-canning processes, 243
Medium, Action in a, 157, 213, 216
- — , The part played by the, 128,
153, 158, 194, 213
Melbourne, Lord, and Faraday's
Xaension, 69
Memory, Trouljles of a defective,
7, 63, 74, 253
Mental education, Views on, 278,
292
Models, Use of, 104, 239
Moigno, Abbe, Reminiscence by,
297
Moll, G. ; his electromagnets, 120 ;
pamphlet on '^ Decline of Sci-
ence," 110, 262
Moore, Miss, Letter to, 207
Morichini's experiments on mag-
netisation by light, 21, 183
806
MICHAEL FARADAY.
Murnhisou, Sir R., ReininisceiicG
Music, Enjoyment of, 24ti
N.
Natural theolo<:^y. Views on, 208
Now electrical machine, 121
Newman, Rev. J. H., and the
Bi'itish Association, Go
Newton, Mr. Jos., Reminiscence
l.y,;2ol
Nobili and Antinori, their mistake,
266
Non-inductive winding, lol)
Notebooks a better ti^st than
examinations, 277
, Faraday's own, 8, 50, 73, 87,
90, 91, 108, 111, 118, 129, 141,
US, loO, 15:j, ir)6, 167, 177, 180,
181, 182, 220
0.
Oersted's discovery of electromag-
netism, 77, 78
Optical glass, Research on, 9'), 100
— - illusions, Research on, 136
relations of electricity, 91,
U9, 15-'), 167, 172, 174, 175
of magnetism, 17G, 182,
220
Order and method, 68, 99, 200
Owen, Lady, Reminiscences by,
236
Oxford and the philosophers, 61
Oxygen, Magnetic properties of.
208
Paris, Dr. J. A., Letters to, 10, 93
Passive state of iron, 167
Peel, Sir- Eobert, 69, 70, 246
Pension: declined, 71; accepted,
72
Percy, Dr. John, Letter to, 253
Permeability, Magnetic, in crystals,
201
, Research on, 206
Personal api^earauce, 4, 18, 74, 255
Phillips, Richard, 7, 44, 52, 54, 57,
59, 61, 84, 87, 193; letters to, 61,
109, 114, 194, 270, 277
Phosphorescence, Lectiu'es on, 136,
219
Pliieker, Julius: on magneto-optic
action, 203 ; shows electric dis-
charge, 240
Poetry by Faraday, 40, 47
Poisson : on Arago's rotations,
107; on magnetic theory, 201
Polar forces in crystals, 94, 20O,
202
Polemics in science hateful, 268
Poles are only doors, 141, 241
Politics, Indifference to, 19, 21, 33,
26S
Pollock, Lady, Remiinsceuccs by,
235, 254, 25"7
Practic-al applications of science,
63, 216, 224, 248, 259
Preaching, Style of, 293
Preservation of Rai^hael's cartoons,
246
Prince Consort, H.R.H. the, 237,
257, 278
Principle of all dynamo machines,
216
Priority in discovery, 265
Professional work tor fees, 51, 61,
274
relinquished, 61 , 274, 275
Professorship of Chemistry at Uni-
versity College, The, ijC), 277 ;
declined, 66
Professorships at the Royal Institu-
tion, 36
Prop'irtional judgment advocated,
242
Public Schools Commission, Evi-
dence given before, 278
P/a/c/i, Caricature in, 252
Pusey and science, 65
■ Q.
QKcirterli/ Journal of Sci.eticf\ 39,
46, 75,^76, 82, 88, 92, 94, 104
Queen Victoria, 257, 297
P.
Radiant matter, 40
Rain torpedo, The, 20
Ray-vibrations, Thoughts on, 103
Regelatiou of ice, 219
Reid, Miss, Reminiscenoes by, 223,
231
Eeligious belief, 51, 289, 291
INDEX.
307
ap-
and
Religious character, 71, 244, '245
Kemuueration of science, 44, (j8,
244, 274
Repulsions, magnetic, New, 190
Research, Royal Institution as
place for, 37
unliamperotl hy other duties,
Researches, Original : the foiu'
degrees of, 241 ; Faraday's first,
70 ; Faraday's last, 220 ;" division
into periods, 75 ; summary of.
Residences :— Weymouth Street, 2 ;
Royal Institution, 13, 68 ; Hamp-
ton Court Cottage, 258
Retardation of discharge, 161
Riebau, George : Faraday's em-
ployer, 3, 7, 22; Faraday
prenticea to, 51 ; letters
messages to, 29, 34
Ring, The famous experiment with
the, 108
Rohinson, H. Crabb, Reminiscences
by, 8, 236
Rontgen on displacement currents,
166
Rotation of plane of polarisation of
light, 177
Rotations, electromagnetic, Dis-
covery of, 51, S3, 87
Royal Institution : foundation of,
35 ; Davy's lectures at, 8, 36,
39 ; jtrecarious state of, 22, 29,
35, 36, 68 ; laboratories of, 36 ;
lectures at the, 37, 166; Christ-
mas lectures, 33, 37, 61, 101,
233, 234, 235, 258 ; Friday night
meetings, 33, 60, 100, 101, 149,
166, 170, 192, 203, 219, 220, 225,
232, 236, 259 ; Presidency offered
and declined, 255
Royal Society : first papers read to
the, 52, 263 ; candidature for
Fellowship in the, 5Q, 57, 50 ;
Faraday's election as Fellow of
the, 59 ; committee on optical
glass, 95, 99 ; Member of Council,
136, 261 ; Presidency offered to
him, 255, 263 ; dissatisfaction
with, 262
Ruhmkorff's induction-coil, 219,
225 '
Rumford, Benjamin Count of :
founds the Royal Institution,
35 ; Faraday dines with, 34
Sacrifice for Science, 6d, 01, 231,
244
Safety-lamp ; Faraday aids Davy
to invent the, 42 ; controversy
about, 269
Salaries paid to scientific men, 41,
68, 244, 274
Sandemauians, 4, 51, 286
Schoubein, Prof., Letters to, 200,
252
Science in education, 279
teaching, Views on, 278 .
Scientific societies, 261
Scoffern, Dr., Anecdote by, 280
Self-induction investigated, 150,
151
Sermons, Faraday's, 293
Shaftesbury, Earl of, 60
Sirium, //ila.s Vestium, 46, 77
Sisters, His letters to his, 32
Smart, B. H,, teaches elocution,
43, 230
Snow-Harris {.siT IliEitis)
Social character, 245
Society of Arts, 14
Source of electromotive force in
cell, 168
South, Sir James, 0, 57, 69, 70, 97,
262
Spark from a magnet, 64, 119, 130
Specific inductive capacity, 159
Spiritualists, Opinion of, 251
Steel, Research on, 82
Stinginess of British Government
towards science, 274
Sturgeon, W. : his invention of
the electromagnet, 102, 226 ; on
Arago's rotations, 107
Submarine cables, 161
Sunday observance, 24, 51, 55, 224,
295, 297
Table-turning explained, 251
Tatum's lectures, 0, 14
Testimonials of candidates, Repug-
nance to, 277
Thames impurities, 252
Thomson, Sir W. {see Kelvin)
Thoughts on ray-vibrations, 193
Thunderstorms enjoyed, 240
Time of propagation of magnetism,
220, 284
308
MICHAEL FARADAY.
Toronto, what its university might
have been, 277, 278
Torpedo, The, 20
Trinity House, Scientific adviser
to, 67, 199, 218, 259
Tubes of force, 211
Turner, J. W, M., R.A., Advice to,
about pigments, 2-46
Tyndall, I'rof. : reminiscences Tiv,
4, 49, 7i, 175, 187, 225, 255, 290,
296, 299 ; his ■' Faraday as a Dis-
coverer," 4, 130, 157, 169, 202;
letters to, 210, 264, 268, 277, 278,
280
TJ.
Utihty oe discoveries, 63, 224, 248
University College, Professorship
in, 66, 277
University of London : Senator of,
275 ; degrees in science, 275
y.
Varley, Cornelius, 5, 294
Velocipede riding, 74
Vesuvius, Ascents of, 22, 33
Vibrations, Thoughts oura}'-, 193
Visits to the sick, 245, 296
Volta, Count Alessandro, Meeting
with, 22
Volta-electric induction, 115
* Voltameter, 146
"VV.
Water, On freezing of, 203
Wellington, The Duke of, on prac-
tical application of discovery,
248
Wheatstone, Sir Charles : on velo-
city of (.Uscharge, 149, 161 ; his
electric chronoscope, 192
Whewell, Rev. W., Correspond-
ence with, about terms, 116, 144,
145, 163, 205
White, Walter, Reminiscences by,
253, 263
Wilham IV., King, 72, 73
Wiseman, Cardinal, Meeting witli,
297
WoUastoD, Dr. W. H., Misunder-
standing with, 51, 56, 57, 58, 84,
89
Woolwich Academy lectures, 6(),
101
Working, Method of, 66, 242, 247
Y.
Young, Dr. T., Letter from, 97
Zecman's magneto -ojitic discovery,
220
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MY COMFORT IN SORROW. By HUGH "' ■ " ' "^ ^ , --- -
MAC.MILLAN, D.D.
MY BiiiLE By the Rij^rht Rev. W . DOVD
CARf ENTER, Bishop of Ripon.
MY FATHER. By the Riglit Rev. ASH-
1 ON OXENDEN, late Bishop of Mon-
treal
My WORK FOR God. By the Rijrht
Rev. Bishop COITERILL.
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MATHESON, D.D.
My Emotional Life. By the Rev.
Preb. CHADWiCK, D.D.
MV BODY. By the Rev. Prof. W.
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D^an BICKERSIETH,
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Creation, By Harvey Goodwin, U.D., | PKA^'ER, By the Rev. Canon Shore,
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Matin and Vesper Bells. Earlier and Later Collected PocnT; (Chiefly
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Me'hodism, Side Lights on the Conflicts of. During the Second
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Moses and Geology ; or, The Harmony ot the Bible with Science.
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Commentary for English Readers. Edited by Eishop Ellicott,
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Protestantism, The History of. By the Rev. J. A, Wvlie, LL.D.
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St. George for England; and other Sermons preached to Children. By
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Models and Common Objects, How to Draw from. By \V. E.
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Object Lessons from Nature. By Prof. L. C. Miall, F.L.S. Fully
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Poetry for Chi dren. Cassell's. 6 Books, id. each; or complete in
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Reader, The Temperance. By J. Dennis Hird. is. or is. 6d.
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Round the Empire. By G. R. Paickin. Fully Illustrated, is. 6d.
Science of Every-Day Life. ByJ. A. Bower, Illustrated, is.
Shakspere's Plays for School Use. g Books. Illustrated. 6d. each
Spelling, A Complete Manual of. ByJ. D. Morell, LL.D. Cheafi
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Technical Manfials. Cassell's. Illustrated throughout. Sixteen
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tjrle of "Lessons in Our Lav/s.' is. od. each.
Selections froiH Casscll ^- Co'i!/>.iiiv''s Puhlicalioni.
looks for ^0iin0 ^Dcople.
Notable Shipwrecks. Revised and Ejilar^cd Ed. tio'i. is.
On Board the IEsmcr4il<l-t ; or, Martin Leifch's Log. By John C.
HrrcHESON. Cheaf' Edition. Illustrated. IS. 6d.
Two Old Ladies, Two Foolish^ Fairies, and a Tom Cat. The Sur:ris-
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lli;rj\VNe. With Four Coloured Plates and other Illustration?;. 3s, Gd.
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The "Victoria" Painting Book for Little Folks. With about 300
Ilkisiraiions. is,
"Little Folks" Half- Yearly Volume. Containing 4°o pages, with
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Bo- Peep. A Cook for the Little Ones. With Original Stories and Verses.
11 ustr.ited with h'lill-page l^'oloured i'lates, ami nucnerons I'ictures
in Colour. Yearly Volume. Picture Boards, 2s. 6d. ; cloth, 3s. 5d.
Etneath the Banne-. Being Narratives of Noble Livts and lirave
Deeds. By F. J. Cross. Illustrated. Limp cloth, is. L loth gilr, 23.
Gocd Morning! Good Night! By F.J.Cross, lllubtated. Limp
cloth, IS., or cloth boards, gilt lettered, 23.
Five Stars in a Little Pool. By Edith CARKI^'G■TON. Illustrated. 3s. 6d.
Merry Girls of England. By L. T. Meade. 3s. 6d.
Beyond the Blue Mountains. By L. T. Meade. 5s.
The Peep of Day. CasseU's IL'iisirated Edition. 2s. 6d.
A Book of Merry Talcs. By Maggie Browne. "Sheila," Isabel
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A Sunday Story-Book. By Maggie Browne, Sam Brownk, and Aunt
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Pleasant Work forlBusy Fingers. By Maggie Browne. Illas .23. 6d,
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Little Mother Bunch. By Mrs. Molesworth. Hid. 2s. 6d.
Heroes of Every-day Life. By Lal'ra Lane. Illustrated. 2s. fd.
Bo.ks for Young People. Illustrated. 3s, 6d. each.
The Cliampion of Odiu; or,
VikiiiK Liiie in tlie Days of
Old. By J. Fred. Hodi/cits.
Eouud by a Spell : ur. The
HunteaWitcliof the Forest.
Hy the Hon. Mrs. ijreene.
Under Bayard'b Banuer. By
Henry Fritli.
Told Out ol School. By A. J.
Daniels.
*3.ed Rose and Tiger Lily. By
L. T. Me.-Jt.
The Ronianc - of Invention, By
James Bu.nley.
*BaBiilul i'lftt^en. By L. T.
Meade.
•The White House at Inch Gow.
By Mrs, titt.
*A Sweet Girl Graduate. By L. T.
The Kiug'3 Command: A Story
lor Girls. Hy ^Ll;T;:;ie :5yminL't.jii.
•The Palace Beautuul. By L r.
Meade,
♦Polly: A New-Fashioned GirL Bv
L. T. Meade. '
"PoUow mv Leader." By Talbot
Bailies Reed.
*A World of Girls: The Story of
a bi;njol. By 1_ T. Meade.
Lost A'uong White Atrie.*U3. L'v
David Ker. '
For Fortune and Glory: AStorv Tf
tIie8oudan War. By Lewis Ilou^h.
Bob Lovell's Caretr. By Edward a
lillis.
* Also /■roc urab/c in Tu/'er-o'- 'inlin-, 63. eacfl.
Selections from Cassell &: Companv's Piih.'ici/i..'ns.
' Feeps Abroad" Library. Che
Eambles Bound Lcndon. Ey C,
L, Mat^:aux. IUii;iralC'-L
irounri andAbcutOldEnglaad.
By C. L. Mat-Jnux, Ilhisira:e±
Paws ani Cla^v-s. By one of ihe
Authors of '■ Poems WTiiteii fcr a
Chilli." Illustrated.
Decisive Events in Hist-rr.
E.- 1 licniii Archer. WithOiiginal
liluitrritit'iis.
The Itu^ E-obinson Cru^oas.
Cloth g-ilL
vt/ Editions. Giit edges, 2s, 6d. each.
PeeoB Abroad for Folks at Horn,?.
lllubtiniC'i tlir-.u^hnut-
■Wild Adventur-si'i Wild Places.
By D-. Gordon StaLLs, K.N. Illus-
trated.
Idoder.i Explorers. By Thorms
Fr?-t llluitra.ed. AVif and Chr-.i^'er
Eaition.
Eaxiy Explorers. Pv T!irm3.s Frost.
Home Cha*. with our Younjj Folits,
Iilu5'.rntf_-J throu^^lj ut.
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ihrou^li^uL
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Pre'=-doin'9 Sword : AStor^'ofthe
Da^-s cf ^\'allace and Eruce.
By Annie S. Swan.
Strone: to Suffer: ^ K'ory of
the Jews. By E. \\ y:iiie.
No. XIII.: or. The Story of
the LostVest.^L A Tale ol"
Eariy Christian Days. By Hinina
Marshill.
By Fire and Sword: A Story of
the Hujuenots. By Thomas
Archer.
Adam Hepburn's Votv: A Tale of
Kirk and Covenant, By Annie
S. Swan.
Through Trial to TrivLmph. By
Madeini B. Hunt.
•'Golden Mottoes" Series, The. Each Book containing 208 pa,-e=;, with
Four fuil-pa^e Ori-Inal Illustrations. Crown 8\'o, cloth gilt, 2s. each.
"Uil Despcrandum." Dy tlie I " Honour is my Guide." Ey Jeanie
Rev. v. LanyLiridt;e, M.A. , Htriiig (Mrs. Adams-Acton).
p -- , i "Aim at a Sure Enci," Bv Emily
Ey Sarah Searchfield.
"He Conquers who Endures." By
Ey Helen j the Author of "May Cunninghams
"Bear and Forbear.''
Pitt.
"Foremost if I Can.'
Attendee.
Trial, "&c
"Wanted— a King " Series. Illustrated. 2s. 6d. each.
Eobin'sEide. By Ellinor Davenport Adams.
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Eairy Taiea in Other Lands. By Julia Goddard.
Cassell's Picture Story Books. Each containing about Si.vt>- Pages of
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Little Talks.
Bright Stars.
Kiirserv Toys.
Pet 6 Posv.
Tiny Tales.
Daisy's Story Bo:)k.
Dot's Story Book.
A Nef-t of StDiiei.
G-cod-Kig-ht Stories.
Chats for Small Chatterers.
Auntie's Stories.
Bii-die'9 Storv Book.
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A Sji^al cf Tales.
DewdrDp Stones.
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Merry Little T^les.
Little^ Tales for Little People.
Li'tle People and Their Pets.
Tf les Told for Sunday.
Simcay Stories for Small People.
Stcr.es and Pictures for Simdav.
Bible PiclnreB forBoys ana Girls,
Firebg-ht Etori '<=.
Svniieht snd Shade.
Kub-a Dub Talee.
FineFeatlierp snd Fluffy Fur.
tGr-mbicE p.nd Scrapes,
little latUe Tales,
Up and Down the Garden,
AH Sorts of Adventures.
Our Holiday Hours.
Ir doors and Out.
£ ooie Fa;m Friends.
Wandering Ways.
Dumb i riends.
Those Golden Sands.
Little Mcthere & theix Children.
Our Pre'.tv Pets.
Our Sc'icoiday Hours.
Cirati-ras Tame,
Crt:atur;-3 "Wild.
Scledhms from. Cassdl % Company s PuhUcalions,
Cassell's Shilling Story Books. All Illustrated, and containing Intc:iest
iiiy Sluriu.'j.
runty and tliG Boys.
'I he Heir of Elmaqlc.
Clamed at Losi. & Roy's Rewai'd
Thorns and Tang-lcs.
The Cuckoo in the Hobin's Neet.
John's Mistake.
I'he llisiovy of Five Little
Pitchers.
SurJy liOb.
The Giant'a Craale.
Shiig and Doll.
The Cost of B-cvenge.
Clever Frank.
Amonff the Redeltins.
The Ferryman of Brill.
Harry Maxwell.
Seventeen Cats.
The World's Workers. A Seri
^\'itll Portraits printed on a lit
Charlf 8 Haddon Spuvgeon. Hy
G. Il^^ldun Pike.
Dr. Arnold ol Kugby. By Roic E,
Sl-I:c.
The Earl of Shaftesbury. By
llciiry I> ih.
Sarah HoLiu'^on, Ag-nes Wes-
ton, aiid Mrs. Meredith. By
h, M. Tunikiiisciii,
Pior. nee Nig tingale, C the-
riue Maraa Fra.^css Ridley
s av(=!rga1, Mi'e. BaNynrd
(' L.N.K."}. By LIZZE ALL-
DRIDGF. (Tobj h-id bound u^
i.i 3". vol. only.)
Mrs. So]nerviiJe and Mary Car-
penter. By riijllis Browne.
Geiier.al Gordon. By the Rev
S. A . Fnv.iine-
Thonias A.Edison and Samuel
I'. E. Morse. By Dr. Dunslow
and J. Marbh Parker.
;s of New and Original VolLime.s.
t as Frontispiece, is. each.
Charles Dickens, By his Eldest
Daughter.
Sir Titus Salt and George
Maore. By J. Burnley,
Dr. Guthrie, Father Mathisw,
Elihu Burrilt. George Livesey.
By John W. Kirron, LL, D.
Sir Henry Havelock and Gniin
Campbell, Lord Clyde. By E. C.
Phillips.
Abraham Lincoln. By Ernest EosUr.
GeoTLie Miilier and Andrew Reed.
P.y E. R. Pitin.in.
Richard Cobdeu. By R. Gowin;?.
Ben.iamin Franklin, By E. M,
Tonikiiisiin.
Handel. By Eliza Clarke. rSwaine.
Turner the Artist. By the Rev, S, A.
George and Robert Stephenson.
Uy C. L. M.itraiiv;.
David Livinffatone^ By Robert i^niilca.
John Cassell. By G. llo'den Pike.
• The above IVor.ks can also It had Three in One I'o!., dolh, j^nU edj^es, 35.
Cassell's Eighteenpenny Story Books, IlUistrated.
Wee Wilhe Winkie.
Three Wee Ulster Lassies.
Up the Ladder.
Dick's Hero; and other Stories.
The Chip Boy.
Roses from Thorns.
The Toitng Eerringtons.
Faith's Father.
By Land and Sea.
Jeff and Leff.
Tom Morris's Error.
"Through Flood— Throug-h Fire" ■
and other Stories.
The Girl with the Golden Locks.
Stories of the Olden Time.
Gift Books for Young People.
Original Illustrations in eacii.
The Boy Hunters of Kentucky.
By Edward S.Ellis.
Red Feather : a I'a'e of
American Frontier.
Edward S. Ellis.
Rhoda's Reward; or,
W^ishes were Horses."
Jack Marston's Anchor.
Frank's Life-Battle
Three Friends.
Fritters. By Sarah Pitt.
The Two Hardeaetles. By Made-
line Bonavia Hunt.
the
By
" If
The
By Popular Authors, With Four
Cloth gilt, IS. 6d, each.
Major Monk's Motto. By the Rev.
F. LanK'lmdgc.
Trixy. By Magi;ie Syniin^toa.
Uncle William's Charges; or. The
Broken Trust.
Tim Thomson's Triah By Geors;
Weathcrly
Ursula's Stumbhug-Block. By Julia
UodJard.
Ruth's Life-Work, By ihc Rev.
Joscpli J...liii^:n.
Sttections from Casse/i 4' Company s Puhlicaiionl.
Cassell's Two-Shilling Story Books. Illustrated.
Peggry, and other Tales.
Stories of the To-wer.
Mr. BurKc's Nieces.
The Top of the Ladder: How to
Reach. It.
Little Fiotsam.
The Children of the Court,
Maid Marjory.
The Four Cats ol the Tipperto:i3,
Little Folks' Sunday BooJi.
Poor NellT.
Aunt Tabitha's Waif3.
In Mischief Again.
Books by Edward S. Ellis. Illustrated. Cloth, 2s. 6d. each.
Klindik-? Wngerets.
Scouts and Comrades : or
'I'eeutnseh, Cliief of the
Shawai^oc b.
Cowmen and Kustlers.
A .'-trange i rafo &nd its
Wonderful Voyages.
Pontiac, Chief of the Ottawas.
In the Days of the Pioneers,
tihod with Silence.
Th=i Phantom of the E.iver.
'I'he Great Cattle Trail.
Thi' Path in the Bavine.
Tile Young R.-ncliers.
Th3 Hunters of the uzark.
The Camp in the Mountains.
Ned in the "Woods. A Tale of
Earl}' Days in i!ie West,
Down ihe Mississ^ippi,
Wed on the Eiver. A Tale of
Indi n River W.irfare.
The Last War Tiau.
Footprints in the Forest.
Up tae Tapajos.
I'^ed m tiie Block House. A
Storvof F:oiieer Life in KcMitirckv
The Lost Trail.
Ca'iip-Fire and Wigwam,
Lost in the Wilds.
Lost in Sa'nca. A Tale of Ad\en.
ture in tlie Navig-ator lilamk.
Tad; or, " GeLting Evcu '■"with
Him,
Books by Edward S. Ellis.
Captured by Indians,
The Daug hter of the Cheftain,
The "World in Pictures."
IS. 6d. each.
All the BuBsins.
Chats about Germany,
'iiie Kastern Wonaerland
(Japan).
Illus'.rated. Cloth, is. 6d. each.
Wolf Ear the Indian.
Abtray in the Forest.
Illustrated throughout Cheap Edition.
Glimpses of South America
The Laud of Temples {i.ndia).
The Isles of the Pacific.
Peeps into China.
The Land of Pyramias lEgypt)
Half-Crown Story Books.
Fairway Island.
HeroeB of the Indian Empire.
The Cost of a Mistake
Working to Win.
Perils Afloat and Eri-^ands
Ashore.
P. eturee of School Life and Bov-
hood. -^
At the South Pole.
thips, Sailors, and the Sea
Books for Ihe Little Ones. Fully Ilkistrated
Cassell's Bobin^on Crufoe.
With i.» 1 1:11st rritions. Cl..th.
3b. 6d; Ki t fdK'C-, 53.
The Old J-'airy Taaes. "With
Oriyii.al Illustrations. Cloth, Is.
Casseds Swiss Family RoMnson.
Illustrated. Clolh, 3s, 6d. ■ eiJt
eiiyes, 53. ^
The Dunday Scrap Book. With
Several Hundred illustrations I'aper
boards, 3s. 6d. ; clotti. gik edges 5s.
Albums for Children, 3s. 6d. each.
Ihe Album for Home. School,
and Pmy. Containing Stones
by Popular Antliors. Iliustr -teJ.
My Cwn Album of ALimala.
Picture Album of All Soits. M'ith
Full-page Illustrations.
The CniL-Chat Album. Illustrated
throughout
CREsell & Company's Complete Catalogue -will be scut post
free on af-plicat.'on to
CASSELL & COMPANY, Limited, Ludgate Hill, London.