4 From Ohm to Helmholtz
Our next five remarkable physicists were born in the thirty-two years from 1789 to
1821. Two came from England, two from Germany and one from America.
Georg Ohm (1789–1854)
Two centuries ago the science and practice of electrical measurement hardly
existed. With a few exceptions, ill-defined expressions relating to quantity
and intensity retarded the progress of electrical investigations. Until well
into the nineteenth century there was no branch of physics in which there
were so many differences of opinion and uncertainties as in those related
to Galvanismus, and scarcely a physicist whose views did not differ from
those of every other upon important principles. Yet amidst this confusion
a discovery was made that was destined to create order out of chaos. This
discovery resulted from the experimental work of Georg Simon Ohm.
The future physicist, born on March 16, 1789 in the Bavarian university
town of Erlangen, was the eldest son of Johann Wolfgang Ohm, master
locksmith, and his wife Maria Elisabeth (n´ee Beck), daughter of a master
tailor. Of the Protestant couple’s seven children, only two others reached
maturity: Martin, born in 1792, and Elisabetha Barbara, born two years later.
Their mother died in 1799, when Georg was scarcely ten years old, but their
father lived until 1822. He was a remarkable autodidact, who gave his sons
a solid education in mathematics, physics, chemistry and philosophy, while
insisting that they also learn the locksmith’s craft. It is to the younger son
Martin that we owe an account of their early life in the (unpublished) autobiography
he left after his death in 1872.
According to this, the mathematical ability of Georg and Martin
was recognized at an early age by a professor of mathematics at the University
of Erlangen named Karl Christian von Langsdorff, who gave them
advice and encouragement. The gymnasium, which was associated with
the university, provided the usual classical instruction with just a little
history, geography and mathematics. After attending the school from 1800
to 1805, Georg Ohm went on to the university and studied mathematics,
physics and philosophy before lack of means and his self-sacrificing
108 From Ohm to Helmholtz
father’s disapproval at his supposed overindulgence in the pleasures of
dancing, billiards and ice-skating forced him to withdraw after just three
semesters.
So in 1806 the seventeen-year-old GeorgOhmbegan what proved to be
a long struggle to earn a living. He started teaching mathematics at a private
school in Gottstadt bei Neydau, a village in the Swiss Canton of Bern. In
his spare time he studied scientific works, such as those of Euler, Laplace
and Lacroix. He was hoping to be able to continue his university education
at Heidelberg but when he sought Langsdorff’s advice, it was that he would
do better to continue reading on his own. After two and a half years at the
school he obtained a position as private tutor in Neuchˆ atel for another two
years. During this period he had some contact with the nearby Pestalozzi
Institute, which had an important influence on his thinking about school
education, as we shall see.
In 1811, in accordance with his father’s wishes, Georg Ohm returned
to the University of Erlangen to obtain his degree. He subsequently taught
mathematics there as a Privatdozent for the next three semesters. Being
a fine draughtsman, he supplemented the meagre income this provided
by making architectural plans of the university hospital and library and
other works. Unfortunately there was little prospect of advancement at the
Georg Ohm (1789–1854) 109
university, and it was to be many years before he obtained a proper university
post. Soon lack of money obliged him to seek employment from the
Bavarian government as a schoolteacher; but the only post he could obtain
was one teaching mathematics and physics at the low-prestige and poorly
attended Realschule in Bamberg, where he worked with great dissatisfaction
until the school’s dissolution in 1816. The next year he was assigned,
in the capacity of auxiliary instructor, to teach a section of mathematics at
the overcrowded Bamberg Oberprim¨arschule. Meanwhile he wrote an elementary
textbook of geometry, dedicated it to his father and published it
in 1817. It was not a success.
Georg Ohm always lived simply. He was a man of marked energy, of
middle height, compactly built, sturdy and strong, what Germans describe
as the Martin Luther type of physiognomy. His eyes were large and penetrating;
his mouth revealed wit, satire and good humour. In diction and
phrase he excelled; moreover, his voice was full, and far into his life it
retained its attractive quality. He was a good, conscientious teacher, but
the conditions under which he worked were unfavourable. For example, the
Bamberg students had benches to sit on, but no desks at which to write.
Their mathematical knowledge at entry was so slight that physics to them
was at first unintelligible. He had progressive ideas about the role of mathematics
in education. The student, he believed, should learn mathematics as
if it were a free product of his own mind, not as a finished product imposed
from without. Ideally, by fostering the idea that the highest life is devoted
to pure knowledge, education should create a self-reliance and self-respect
capable of withstanding all vicissitudes. These views reflected not only his
own early education but also the years of isolation in Switzerland and of
personal and intellectual deprivation in Bamberg.
In 1817, the year his geometry textbook appeared, Georg Ohm was
appointed to the position of Oberlehrer of mathematics and physics at the
recently reformed Jesuit gymnasium in Cologne. He found there a library
and facilities for experimental work. Equally importantly he found congenial
colleagues who were enthusiastic about learning and teaching. Encouraged
by this, Ohm was able to combine research in the well-equipped
laboratory with his duties as a teacher; his students found him inspiring.
He prepared himself by studying the French classics – at first Lagrange,
Legendre, Biot and Poisson, later Fourier and Fresnel. However, it was
Oersted’s discovery of electromagnetism in 1820 that led him towards experimental
work in electricity and magnetism, particularly the elucidation of
the galvanic circuit.
110 From Ohm to Helmholtz
Meanwhile Georg Ohm’s younger brother Martin was getting on well.
He too had spent some years as a schoolteacher, in the course of which he
married a Swiss lady. He had written a textbook on number theory and,
perhaps as a result of this, had secured the position of Privatdozent at Berlin
University in 1821, which he combined with some teaching at the prestigious
Friedrich Wilhelm Gymnasium. In Berlin he made a good impression
on some of the influential members of the Academy of Sciences, which
led to his appointment as associate professor at the university in 1824, followed
fifteen years later by promotion to full professor. By contrast, his
brother Georg was overburdened with teaching and had become convinced
that his life had run into a dead end, that he must extricate himself from
what had become a stultifying situation in Cologne. Fearing that otherwise
he would never marry, he was determined to prove himself to the world
and to have something solid to support his efforts to obtain a position in
a more stimulating environment. He decided that he must devote himself
full-time to research and persuaded the authorities to grant him leave of
absence at half-pay for a whole year to pursue it in Berlin, alongside his more
successful brother Martin. The outcome was his masterpiece, the treatise
Die galvanische Kette, mathematisch bearbeitet, known in English as The
Galvanic Circuit, which appeared in 1827. This describes how resistance,
strength of current and potential difference are related. Among other results
this contains the fundamental law which bears his name.
Georg Ohm structured his theories in conscious imitation of Fourier’s
Th´eorie analytique de chaleur of 1822, a fact that may have led him to deemphasize
its experimental side in favour of an abstract deductive rigour, in
striking contrast to the inductivist tone of his earlier writings. Although he
did not spell out how, he wished the analogy between electricity and heat
to be taken seriously, not as something coincidental but as revealing some
underlying relationship. While Ohm’s law was independently confirmed by
other scientists, his theories came under attack, mainly because they were
based on experiment and observation rather than philosophical speculation
in the spirit of Hegel, whose romantic ideas were much in vogue at the time.
The criticism to which he was subjected demoralized Ohm, who resigned
from his position in Cologne in order to remain in Berlin with his brother.
For the next six years he was without a regular appointment, earning
a pittance by teaching cadets at the institution which later became the
Military Academy. A university post remained his goal, but in Prussia
the higher academic doors were closed to him. In influential quarters his
theories were rejected, if they were understood at all. Moreover, his brother
Georg Ohm (1789–1854) 111
Martin, with whom he was living, had acquired the reputation of being
a dangerous revolutionary. So in 1833 Georg decided to return to Bavaria,
hoping for a position at the University of Munich. In this he was unsuccessful;
instead, he was appointed professor of physics at the Polytechnic
Institute in Nuremberg, where he remained for the next fifteen years. Unfortunately,
apart from the title of professor, the position was no improvement
over the one he had held in Cologne.
After the publication of Die galvanische Kette, Georg Ohm turned
away from electrical research and directed his attention towards molecular
physics. His aim was to investigate, with the aid of analytical mechanics, the
form, magnitude and mode of operation of atoms, but he never had enough
free time to undertake such an ambitious project. Nevertheless, he continued
scientific research in other areas, notably he anticipated Helmholtz
when he discovered in 1843 that the human ear recognizes only sinusoidal
waves as pure tones, automatically performing an analysis of any periodic
sound into its component tones. Die galvanische Kette was translated into
English in 1841, fourteen years after its original publication, into Italian in
1847 and into French in 1860, although parts of the book were translated
earlier.
Increasingly, however, Georg Ohm was given other responsibilities,
in addition to his teaching duties, and these effectively put an end to his
researches into molecular physics. For some years he was Rector of the
Polytechnic Institute, while he also served as Inspector of Scientific Education
for the Bavarian State. It was not until 1849 that he achieved his
ambition of a senior post at the University of Munich, initially as associate
professor, then as full professor three years later. He was also given a seat
in the Senate and made curator of the mathematical–physical collection of
the Bavarian Academy. His last important piece of research was in 1852–3,
when he investigated interference phenomena in uni-axial crystals. By this
time, however, he was over sixty and almost blind, although unable to
retire because in Bavaria there were no pensions for university professors.
Following a stroke he died in Munich on July 6, 1854, having given what
proved to be his last lecture the previous day, and was buried in the Sudliche
Friedhof cemetery.
Georg Ohm had to wait a long time before his scientific work was
properly appreciated in his homeland, and for some years it remained largely
unknown anywhere else. However, by the early 1830s it was beginning to
be used by at least the younger German physicists working in electrical
science. British and French physicists seem not to have become aware of its
112 From Ohm to Helmholtz
profound implications until the late 1830s, but the situation improved when
the Royal Society of London awarded him its prestigious Copley medal,
particularly referring to his research on the conductivity of metals and on
galvanometers. It was acknowledged that it would have been of great value
to British investigators if they had known of his work earlier. Specifically,
Faraday, whose profile follows, was referring to Georg when he wrote in 1830
that ‘Not understanding German, it is with extreme regret I confess I have
not access and cannot do justice to the many valuable papers in experimental
electricity published in that language.’ Even ten years later the Manchester
physicist James Joule announced the law we know as Ohm’s law as if it were
a new discovery in a short paper submitted to the Royal Society.
As a Copley medallist and foreign member of the Royal Society, a
corresponding member of the Berlin and Turin Academies, a full member of
the Bavarian Academy and Knight of the Order of St Michael, Ohm was not
lacking in honours. Although at times he was miserably poor, it was said
that he displayed no bitterness as to his lot. Germany had been destabilized
by the Napoleonic wars at a crucial stage in his career, and, although Ohm
was not involved in the fighting, it was a miserable period for civilians as
well as soldiers. There can be little doubt that he could have contributed far
more to science if he had had better opportunity to do so. The Polytechnic
Institute in Nuremberg where he spent the major part of his career is now
the Ohm Institute; in front of it is a statue of Georg Ohm by Wilhelm von
Ru¨ mann, which was unveiled in 1895.
Michael Faraday (1791–1867)
James, the father of Michael Faraday, was the blacksmith of Outhgill, a
village near Kirkby Stephen in Westmorland. In 1786 he married Margaret
Hastwell, a farmer’s daughter, and soon afterwards they moved south and
settled in Newington Butts, south of the Thames near London Bridge. The
future scientist was born there on September 22, 1791, the third of four children,
of whom his sister Elizabeth and brother Robert were a few years older
and his sister Margaret a few years younger. The letters of Faraday’s parents
display intelligence and great religious earnestness. The father died in 1810
after years of poor health, leaving his impoverished widow to support herself
and the children by taking in lodgers. Her influence on her son Michael
was profound; she lived until 1838, by which time he had been recognized
as the greatest experimental physicist in the world.
From Newington the Faraday family moved house several times, ending
up near Manchester Square, on what was then the western fringe of
Michael Faraday (1791–1867) 113
London. Up to the age of thirteen Michael’s education ‘consisted of little
more than the rudiments of reading, writing and arithmetic at a common
day school’, he recalled, ‘My hours out of school were passed at home and
in the streets.’ In the same area there was a bookbinder and stationer’s shop
kept by a French ´emigr´e named Riebau, to whom the youth was apprenticed.
Faraday lived at this establishment for eight years, working as a bookbinder
and acquiring manual skills that later stood him in good stead in his experimental
work. In these years he was strongly influenced by a book by the
eighteenth-century divine Isaac Watts entitled On the Improvement of the
Mind. He followed its suggestions for self-improvement, such as the formation
of a discussion group with others of similar age who were interested
in the exchange of ideas. When his apprenticeship with Riebeau expired, he
went on to work for another French ´emigr´e, with whom he was less happy.
Faraday’s contemporaries describe him as proud, kind and gentle, simple
both in manner and in attitude and with extraordinary animation of
countenance. His voice was pleasant and his laugh hearty. In height, he was
somewhat below average. His head from forehead to back was so long that
his hats had to be specially made for him. In youth his hair was brown,
curling naturally; later in life it approached white and was always parted at
the centre. It was from his mother that he acquired much of his character,
114 From Ohm to Helmholtz
especially the rejection of all social and political distinctions. His parents
were both Sandemanians, as he became himself. After the Restoration John
Sandeman, with his father-in-law John Glas, had seceded from the Presbyterians
and founded this small religious sect, which stressed the love of the
Creator. Sandemanians believe in the literal truth of the Scripture, pledging
themselves to live according to the Bible and in imitation of Christ.
Faraday’s interest in science was first aroused by a chance reading of
the article ‘electricity’ in a copy of the Encyclopaedia Britannica that he
was rebinding. The article, which was written by one James Tytler, was
somewhat heretical in its views, but it stimulated Faraday to try to verify
the statements in it, and much later the influence of Tytler’s unorthodox
theories regarding the nature of electricity was still apparent. Meanwhile
he took advantage of some of the lectures on scientific subjects being given
in London, especially those given by a certain John Tatum, who gathered
together a group of young men at his home every Wednesday night to discuss
scientific matters and make use of his library. They called themselves
the City Philosophical Society; this group seems to have played a part in
the foundation of Birkbeck College. In this way Faraday obtained a basic
scientific education, covering electricity, galvanism, hydrostatics, optics,
geology, theoretical mechanics, chemistry, astronomy and meteorology.
It was chemistry that interested Faraday most at this stage in his
career. Here he set great store by Jane Marcet’s book Conversations on
Chemistry, Intended more Especially for the Female Sex. This popular work
had been much influenced by the lectures of Davy which she had attended at
the Royal Institution. A customer of Riebau’s gave Faraday tickets to attend
Davy’s lectures himself. He went and from the gallery took careful notes;
thereupon he adopted Davy as his role model. Soon an accident opened up
an opportunity for him to leave the craft of bookbinding behind him and
begin a scientific career. Davy had temporarily been blinded as a result of
an explosion during a chemical experiment, so he needed an amanuensis.
Faraday was recommended to Davy, who was much impressed by his work.
When Davy’s assistant at the Royal Institution was dismissed for misconduct
in 1813, Faraday was appointed in his place.
Davy was a close friend of Coleridge, who brought to England the
philosophical ideas of Kant and his followers. These ideas helped to provide a
unity to Davy’s work, and even more strongly that of Faraday, because it was
in tune with his religious beliefs. His science was characterized by brilliant
flashes of insight soundly supported by experimental evidence. Davy exerted
a most important influence on Faraday’s intellectual development, which
Michael Faraday (1791–1867) 115
took place gradually. In the autumn of 1813 Davy and his wife went abroad
on an extended honeymoon, taking Faraday with them as factotum. The
party went to France, Switzerland and Italy, calling on eminent men of
science, such asAmp`ere andVolta, wherever possible. Unfortunately Davy’s
wife, who was something of a snob, insisted on treating Faraday as a personal
servant. On their return to London, after eighteen months on the continent,
Faraday began to try his hand at experimental work; encouraged by Davy, he
published his conclusions in the Quarterly Journal of Physics, until in 1820
he had a paper accepted for the more prestigious Philosophical Transactions
of the Royal Society.
About this time Faraday made the acquaintance of Sarah Barnard, the
sister of one of the friends he had made at the City Philosophical Society,
and they were married in 1821; she was twenty-one, he twenty-nine. Like
him she came of a Sandemanian family; Sandemanians tended to marry, and
to find most of their social life, within the sect. Soon after marriage Faraday
became a full member of the sect, which played such an important part in
his life, and made his confession of faith, later becoming a Deacon and later
still an Elder, one of three responsible for the administration of the church
in London. ‘A just and faithful knight of God’, said his fellow-scientist John
Tyndall, ‘I think that a good deal of Faraday’s week-day strength and persistency
might be referred to his Sunday Exercises. He drinks from a fount
on Sunday which refreshes his soul for a week.’ Exclusion from the church
was a severe punishment, which he suffered on at least one occasion.
By this time Faraday hardly needed Davy’s patronage any more. Davy
was never able to accept Faraday as a social equal, whereas John Herschel,
son of the great astronomer, readily did so. When the two men first met
Faraday was still a lowly assistant at the Royal Institution, whereas
Herschel, his junior by six months, was a graduate of Cambridge, where he
had been senior Wrangler and Smith’s prizeman, and was already a fellow
of the Royal Society. They became firm friends and Herschel never failed
to provide Faraday with encouragement and support when necessary. For
example, he was one of the first to sign the certificate nominating Faraday for
the fellowship of the Royal Society, whereas Davy, who was president at the
time, made strenuous efforts to have the nomination withdrawn. Exactly
why Davy did so is unknown, but Faraday was nevertheless elected fellow
in 1823. Davy nominated Faraday for the position of secretary of the newly
founded club, the Athenaeum; however, as soon as the club had become well
established he resigned the office of secretary while remaining an ordinary
member.
116 From Ohm to Helmholtz
The next twenty years saw Faraday make one scientific discovery
after another, initially in chemistry and later in electricity, where his classic
investigations laid the foundations for the science we know today. His
earliest scientific work was on the liquification of gases, in 1823; his first
major contribution to science, the discovery of benzene, followed two years
later. However, it is with electricity and especially electrochemistry that
his name is permanently linked. After discovering the process of electrolysis
in 1832, he went on to work out the laws which control it, no mean
feat for a scientist without mathematical training. He was thirty when he
discovered electromagnetic rotations, forty when he discovered induction,
using it to produce the first electrical generator and transformer, and fiftyfour
when he discovered the magneto-optical effect and diamagnetism. Not
many scientists have begun their creative lives so late or continued so long.
Faraday’s most famous work is his Experimental Researches in Electricity,
in three volumes, made up of papers that had mostly originally appeared
in the Philosophical Transactions or the Philosophical Magazine. This was
followed by his similar Experimental Researches in Chemistry and Physics.
By 1825 the financial position of the Royal Institution left much to be
desired. Faraday helped to strengthen it by instituting the celebrated series
of Friday evening discourses, of which he gave over a hundred himself. These
served to educate the English upper class in science, particularly those of its
members with influence in government and the educational establishment.
To prepare himself for lecturing, at which he excelled, Faraday took lessons
in elocution, and he had some experience as a preacher, but these were
of little importance compared with the care he took over preparation and
presentation. He thought that, even though a lecture might be written out,
it should not be read to the audience. His influence as a lecturer consisted
less in the logical and lucid arrangement of his materials than in the grace,
earnestness and refinement of his whole demeanour. ‘Except by those well
acquainted with his subjects, his Friday evening discourses were sometimes
difficult to follow’, said Tyndall, ‘but he exercised a magic on his hearers
which often sent them away persuaded that they knew all about a subject of
which they knew but little.’ One of his auditors spoke of his gleaming eyes,
the hair streaming out from his head, his moving hands and his irresistible
eloquence: his audience took fire with him and every face was flushed.
Another commented that ‘no attentive listener ever came away from one of
Faraday’s lectures without having the limits of his spiritual vision enlarged,
or without feeling that his imagination had been stimulated to something
beyond the mere exposition of physical facts’.
Michael Faraday (1791–1867) 117
The Faradays lived in rooms over the Royal Institution, known as the
Upper Chambers, from which a back staircase led directly to the laboratory
in the basement, where he enjoyed good facilities for his experimental
work. He gave regular courses, in addition to the routine lectures, and was
heavily involved in the organization of the various activities of the Institution,
of which he was effectively administrator. From 1829 to 1852 he also
held the position of professor of chemistry at the Royal Military Academy
at Woolwich. He was also greatly in demand to give practical advice, commercial
analysis, expert testimony and public service generally. In 1836, for
example, he became chief scientific adviser to Trinity House, the ancient
foundation responsible for the erection and maintenance of coastal installations
such as lighthouses and buoys; the electrification of lighthouses was
just in its early stages. He gave advice on the prosecution of the war against
Russia. In 1841, faced with too many calls on his time and energy, Faraday
experienced a nervous breakdown; he had previously sometimes suffered
from loss of memory and dizziness. Memoranda written by Faraday at
this time show that his mind was seriously disturbed; there is a theory
that his condition might have been due to mercury poisoning. He went to
Switzerland accompanied by his wife, who was also in poor health, and his
brother-in-law the watercolourist George Barnard. As soon as his health permitted
he resumed scientific work, this time on magnetism, but the important
discoveries all precede the breakdown. There is a parallel with Isaac
Newton, who also experienced a nervous breakdown, but, unlike Faraday,
Newton never recovered his scientific drive.
In early days Faraday had added to his unduly modest salary from the
Royal Institution a supplementary income from what he called ‘commercial
work’. This supplement might have become important to him, but just
as it showed signs of expansion Faraday abandoned it. The fall in his commercial
income was correlated with his discovery of magneto-electricity,
when worldly gains became contemptible compared with the rich scientific
landscape which opened up before him. In 1835 the Tory Prime Minister
Sir Robert Peel wished to offer Faraday a Civil List pension, but, following
a change of government, it fell to the Whig Lord Melbourne to make the
offer, which he did with such ill-grace that the proud Faraday felt insulted
and turned it down. When this became public knowledge there was uproar;
the King intervened, Melbourne apologised and Faraday accepted the pension
of £300. Among the honours he received from other countries was
membership of the Legion of Honour and a knighthood from the King of
Prussia; also he was a foreign member of the Paris Academy.
118 From Ohm to Helmholtz
Faraday maintained a strict separation between his religion and his
science, but both were of the utmost importance to him. The tenderness of
his nature made it difficult for him to resist the appeal of distress, but he
preferred to distribute his charitable gifts through some organization that
assured him they would be well bestowed. Faraday had been interested in
the visual arts from an early age and was personally acquainted with some of
the leading artists of his day. He gave advice on the conservation of works
of art to institutions such as the British Museum, the National Gallery
andWestminster Abbey. He collected drawings, engravings, lithographs and
photographs of scientists and other notables of his day. Although himself
not one of the pioneers of photography, he was much interested in this new
development.
By the middle of the 1850s Faraday had gone as far in research as he
could, and, as we shall see, his work was taken up by the young Scotsman
Clerk Maxwell, whose theory of the electromagnetic field built on the foundations
that Faraday had laid. In fact he, before others, noticed the failing
strength of his brain and declined to impose on it a weight greater than it
could bear. His mind deteriorated rapidly, and, even if he had been able
to understand Maxwell’s mathematics, it is doubtful whether he would
have been able to follow Maxwell’s reasoning and appreciate these new
developments.
As his mental faculties declined, Faraday retreated gracefully from
the scientific world. He turned down invitations to accept the presidency
of the Royal Society and that of the Royal Institution; he found the idea of
the latter position so upsetting that it brought on another nervous crisis.
He concentrated what remained of his energies on his teaching functions at
the Royal Institution. It was more in his Christmas lectures to audiences
of children, rather than in those he addressed to adults, that his unequalled
ability as a teacher was most in evidence. His Christmas lectures for a juvenile
audience for 1859/60, on the various forces of matter, and for 1860/61,
on the chemical history of a candle, were edited by William Crookes and
have become classics. However, even his lecturing abilities began to fade,
and he was forced to abandon the lectern in 1861, after experiencing fits of
giddiness and loss of memory. He arranged for Tyndall to deputise for him
at the Royal Institution. In the closing years of his life the Faradays lived at
Hampton Court, not in the palace but in a house on the Green placed
at his disposal by Queen Victoria at the suggestion of Albert, the Prince
Consort. Michael Faraday died in his seventy-fifth year on August 25, 1857
from ‘decay of nature’; at his own request he was buried without pomp or
George Green (1793–1841) 119
ceremony in a simple grave in Highgate cemetery. ‘A mighty investigator,’
said Tyndall at his funeral, ‘nothing could equal his power and sweetness as
a lecturer.’ His wife Sarah died in 1879; they left no descendants.
George Green (1793–1841)
In 1828 an essay entitled The Application of Mathematical Analysis to the
Theories of Electricity and Magnetism was published. The author was a
largely self-educated thirty-five-year-old miller named George Green. The
Essay attracted little attention at the time but is now regarded as one of the
landmarks of modern mathematical physics. The story of his life is one of
the most remarkable in this collection.
A baker named George Green lived in Nottingham, a historic town
in the Midlands of England. In 1791 he married a woman named Sarah
Butler. Her father helped him set up a bakery in the town centre. Their
only son, also named George, was born on July 14, 1793. Two years later
their daughter Ann was born; she later married a cousin, William Tomlin,
who is the source of most of what is known about the life of the future
mathematical physicist.
George Green junior was eight years old in 1801 when he went to
Robert Goodacre’s Academy, the best school in the town. Goodacre wrote
textbooks on arithmetic and in later years would travel in Britain and the
USA giving lectures on popular science. On the roof of the building he constructed
an astronomical observatory. The school was well equipped with
scientific instruments, and probably the boy learned to use them in the
short time he was at the school. We know that, when it was enlarged some
years later, it offered teaching in reading, English grammar, penmanship and
arithmetic. Young Green was probably taught these. It also offered geography,
the use of globes, mathematics, book-keeping, English composition,
natural philosophy, astronomy, history, Latin and Greek. French was taught
by a native; there seems no doubt that the boy learned some French at some
stage. Later Tomlin wrote that his ‘profound knowledge of mathematics’
soon exceeded his schoolmaster’s.
Not many of the pupils at the Academy stayed more than a year or
two, so it was unremarkable that the boy was withdrawn after four terms.
Then, at the age of nine, he started work in his father’s bakery. The business
was prospering and George Green senior, who already owned some houses
in Nottingham itself, was able in 1807 to purchase an attractive plot of land
in the nearby village of Sneinton, only a mile from the town centre. The land
stood on a hill, and on this site he built a ‘brick wind corn-mill’. The mill
120 From Ohm to Helmholtz
itself, which stood fifty feet high, was surrounded by auxiliary buildings,
including a house for the miller. This was occupied by a manager, while the
family continued to live in Nottingham and run the bakery.
Some ten years later George Green senior built a substantial family
house alongside the mill, with two front rooms and five bedrooms, and
moved there with his wife and son. As Tomlin tells us, the son ‘lived with
his parents until the termination of their lives and duly rendered assistance
to his father in the prosecution of his businesses’. When George Green senior
died in 1829 at the age of seventy, his wife having predeceased him by four
years, he left money and his Nottingham property to his daughter Ann
Tomlin and the milling business to his son. There was nothing romantic
about being a miller. It was exhausting work; moreover, the dust from the
operation accumulated in the lungs and caused a disease similar to silicosis.
Tomlin goes on to say that the work was ‘irksome to the son who at a very
early age and with in youth a frail constitution pursued with undeviating
constancy, the same as in his more mature years, an intense application
to mathematics or whatever other acquirements might become necessary
thereto’.
We must now go back some years to 1823, when George Green senior
was still alive. This was a period when the industrial and scientific revolution
had led to the formation of various intellectual and cultural institutions
in some of the more enterprising English towns. In Nottingham such
an institution was located in a building called Bromley House, and known
by that name. It had been founded in 1816 and soon became the popular
venue for the wealthier citizens, the leisured, the cultivated and the philanthropic.
It was a meeting-place for the committees of the newly formed
Nottingham School of Medicine and of the Ladies’ Bible Society, the Literary
and Debating Society, the Geological, the Natural History, the Geographical
and the Astronomical Societies. The Amateur Musical Society also
met there; artists exhibited there. However, most importantly, there was
a library, called the Nottingham Subscription Library, which non-members
could use for a fee. When Green became a member there were about a hundred
subscribers, who were mainly members of the leading town and county
families or the more prominent local firms. There were also professional
men, doctors, lawyers and so on.
Originally £600 had been spent on books for the library, but further
purchases were made, and members could ask for particular books to be
ordered. They were mostly in the categories of literature, history and biography,
with some travel and natural history. When Green was a member, the
George Green (1793–1841) 121
catalogue listed no more than a dozen serious scientific and mathematical
works, including treatises by Lagrange and Laplace, but none of them are
the particular books to which Green refers or makes use of in the Essay.
There was, however, a set of the Philosophical Transactions of the Royal
Society. In its pages Green would have been able to follow the course of
discoveries in science for the previous 160 years.
At the same time, one has to ask what was happening between the
time he left school, at the age of nine, and the time he joined the library, at
the age of thirty?We know that he worked in the bakery and the mill, but it
seems he used to retreat to a room on the top floor of the mill to study whenever
he could. If someone was guiding his studies, the most likely candidate
seems to be Toplis, headmaster of the Free Grammar School in Nottingham.
Toplis was the second head who was a Cambridge graduate in mathematics.
He was in his twenties when he came to Nottingham and stayed until 1819,
by which time Green was twenty-six. After that he returned to Cambridge
as a fellow of Queens College. (The college library contained a good collection
of books on mathematics in which the French mathematicians of
the time were particularly well represented.) The methods Green used are
distinctively French. As well as with Laplace’s magnum opus, he seems to
have become familiar with papers by Biot, Coulomb and Poisson, among
others.
Toplis was among the few who recognized that Britain was being left
far behind in the field of mathematical research after more than a century of
steady progress on the continent, particularly in France. He was an enthusiast
for the work of the French school and had translated the first two
books of Laplace’sM´ecanique c´ eleste into English. His translation was published
in Nottingham in 1814, when Green was twenty-one, and Toplis
presented a copy to the Nottingham Subscription Library when he became
a member. Until about 1817 the Green family lived very close to the Free
Grammar School, where Toplis was resident. Although there is no certainty
that Toplis was Green’s mentor, the circumstantial evidence is persuasive.
Five years after Green joined the library his first and greatest work, the
Essay on Electricity and Magnetism, was published in Nottingham by private
subscription in 1828. There were 51 subscribers, half of whom were
fellow members of Bromley House. It was one of the first attempts to apply
mathematical analysis to electrical phenomena and was of such importance
that it has been described as the beginning of modern mathematical physics
in Britain. In it Green gave the name potential to Laplace’s analytical device
and used it in relation to electricity, where it proved an invaluable tool in the
122 From Ohm to Helmholtz
development of electromagnetic theory. The Essay is also important for the
introduction of new mathematical techniques, known nowadays as Green
functions, which are regularly used throughout mathematical physics, and
Green’s theorem, which is fundamental in differential geometry as well.
Such a seminal work should have been published by one of the learned societies,
rather than in such an obscure way, but Green seems to have thought
it would not be accepted, ‘coming from an unknown individual’. Unfortunately
the result was that the Essay attracted little attention, and, greatly
discouraged, Green seems to have given up his investigations for the next
few years.
Green now had full responsibility for running the family business,
which he had inherited. Like his father, however, he relied on a manager,
named Smith, who had a daughter, Jane, who was nine years younger than
Green. When she was twenty-two she bore him a daughter, Jane, who was
known as Jane Smith, like her mother. Later two sons and three daughters
were born and known by the surname of Green, although the parents never
married; only the first daughter was known by the other surname.
One day in January 1830 Green had a conversation with a certain
Mr Kidd from the city of Lincoln, which had highly significant consequences.
Green had dedicated his Essay to the Duke of Newcastle, who
controlled the representation of Nottingham in Parliament. He had also
sent a copy on publication to a subscriber living near Lincoln, Sir Edward
Ffrench Bromhead, who replied most encouragingly and apparently offered
to send any further mathematical work by Green to one of the learned societies.
Unfortunately the diffident Green did not take up this offer – someone
apparently told him it was just a polite gesture – but Kidd assured him that
it was intended seriously. So, nearly two years after publication of the Essay,
Green wrote a long, apologetic letter to Sir Edward explaining the reason
for the delay and promising to take up the offer if it still held good. This
started a correspondence between the Lincolnshire baronet, himself a mathematician,
and Green, who seems to have visited his seat of Thurlby Hall
on several occasions.
Sir Edward had been one of the Cambridge students who founded the
Analytical Society in 1819. This body, which later became the Cambridge
Philosophical Society, helped to rescue Cambridge science from its torpid
condition. After graduating from Cambridge in 1812, he studied law at the
Inner Temple and, on returning to Lincolnshire, began playing a prominent
part in city and county affairs. However, he retained his Cambridge
connections and invited Green to accompany him on a visit to his alma
George Green (1793–1841) 123
mater. Green declined: ‘You were kind enough to mention a journey to
Cambridge on June 24th to see your friends Herschel, Babbage and others
who constitute the chivalry of British science. Being as yet only a beginner
I think I have no right to go there and must defer that pleasure until I
shall have become tolerably respectable as a man of science should that day
ever arrive.’ The possibility of going up to Cambridge as an undergraduate
had already been mentioned by Green in April of that year. He naturally
turned to Sir Edward for advice as to ‘which college would be most suitable
for a person of my age and imperfect classical attainments’. Unsurprisingly,
Sir Edward recommended his own college, Gonville and Caius. In preparation
for his move to Cambridge, Green, having leased the mill after his
father’s death, let the family house: we have no information on the whereabouts
of Jane, who by this time had four children. He resigned from the
Nottingham Subscription Library, having had the satisfaction of presenting
a copy of his first memoir published in Cambridge the previous year.
By the end of 1833 Green had written three memoirs. Two were published
by the Cambridge Philosophical Society and one by the Royal Society of
Edinburgh.
Green arrived in Cambridge early in October 1833 and was admitted
as an undergraduate to the college usually known as Caius (pronounced
keys), a community of some 170 students and twenty fellows. He was much
older than the normal age of admission. On his departure for Cambridge,
Sir Edward had given him letters of introduction ‘to some of the most distinguished
characters of the university that he might keep his object steadily
in view under some awe of their names and look upwards, not of course
with any view of trespassing on the social distinctions of the university,
in my time more marked than at present, but that he might venture to
ask for advice under any emergency’. Green managed to pass the general
examination in Latin, Greek and ecclesiastical history. After the first eight
months he wrote to Sir Edward: ‘I am very happy here and am I fear too
much pleased with Cambridge. This takes me in some measures from those
pursuits which ought to be my proper business, but I hope on my return to
lay aside my freshness and become a regular Second Year Man.’
The Senate House (or Tripos) examination dominated the undergraduate
course. It consisted of 200 questions to be answered over seven days
in midwinter in the unheated building. The first three days were on book
work, the books being the Elements of Euclid and the Principia, and passing
on these was sufficient for most students. For the better students it was
just a question of speed. However, for those aspiring to honours there were
124 From Ohm to Helmholtz
four more days of more difficult problems over a wide range of subjects. The
lectures were optional; for most students the bulk of the instruction came
from a private tutor or coach, but it is unlikely that Green could afford this
extra expense.
Green achieved fourth place on the order of merit in the notorious
examination and thereby became eligible for a college fellowship. As soon
as a vacancy occurred, two years later, he was elected. Fellowships carried
the right to rooms in college and meals at the common table, free of charge,
and a small stipend. His duties were far from onerous. He is known to
have set and supervised examinations; his manner on such occasions was
recorded as gentle and pleasant. As a Cambridge graduate he could attend
meetings of the Philosophical Society and present his papers there in person.
Three papers of his were published in 1838 and three more the next year.
Two were on hydrodynamics, two were on the propagation of light and two
on the propagation of sound. Thus Green had altogether eight papers published
in Cambridge, one in Edinburgh and, of course, the original Essay in
Nottingham. The Essay, on electricity and magnetism, and the last memoir
on the propagation of sound are considered to be his most important works.
During his six years at the university he had achieved a considerable reputation.
‘He stood head and shoulders above all his contemporaries inside
and outside the university’, wrote someone who was there at the time.
Yet only six months after his admission to the fellowship at the end
of October 1839 he took the coach home to Nottingham for the last time.
In the words of his cousin Tomlin: ‘He returned, indisposed after enjoying
many years of excellent health in Sneinton, Alas! With the opinion that he
should never recover from his illness and which became verified in little
more than a year’s time by his decease on May 31, 1841.’ For all his six
years in Cambridge and his reputation there, Green came home to die in
relative obscurity. All the local newspaper had to say was the following: ‘we
believe he was the son of a miller, residing near to Nottingham, but having
a taste for study, he applied his gifted mind to the study of mathematics, in
which he made rapid progress. In Sir Edward Ffrench Bromhead, Bart., he
found a warm friend, and to his influence he owed much, while studying
at Cambridge. Had his life been prolonged, he might have stood eminently
high as a mathematician.’
Green died of influenza aged forty-seven, in a house in Nottingham
occupied by his partner Jane Smith and her family of seven children. Clara,
the youngest, had been born the previous year, only a few weeks after his
final return from Cambridge. Jane Smith was the one who reported his
Joseph Henry (1797–1878) 125
death; and she was with him at the end. He was buried with his parents
in St Stephen’s churchyard in Sneinton. On the gravestone he is described
as ‘Fellow of Caius College, Cambridge’. In the will he had made some
ten months previously, he describes himself as ‘late of Sneinton in the
County of Nottingham and now of Caius College, Cambridge, Fellow of such
College’. Whatever the immediate cause of death, it seems most likely that
the ‘indisposition’ which caused him to return home was the miller’s version
of silicosis, although Felix Klein, in his account of the development of
mathematics in the nineteenth century, attributed it to alcoholism; perhaps
he heard this from Green’s contemporary the mathematician James Joseph
Sylvester.
In time the mill at Sneinton fell into disrepair. Any papers that Green
may have left seem to have been destroyed. His descendants were unaware
of their genius of an ancestor. Recently, however, the city has begun to take
pride in one of its most distinguished citizens. The mill has been restored
and a little museum added, in which one may learn about Green’s work and
its consequences, and perhaps purchase some flour ground at the mill. When
the bicentenary of Green’s birth occurred in 1993, scientific conferences
were held to discuss the influence of his work, and a ceremony was held at
Westminster Abbey, where a simple plaque was unveiled in his memory. It
can be found near the base of the monument to Newton.
Joseph Henry (1797–1878)
The American physicist Joseph Henry made important contributions to the
investigation of electromagnetism. He built the largest electromagnet then
known, which could lift 300 kilograms; he also discovered electromagnetic
induction, independently of Faraday, and invented an early formof the telegraph
and the electrical relay. On principle he never patented any of his
inventions, which when exploited commercially made others rich but not
the inventor. The unit of inductance is named after him. Sadly, his recognition
as a great experimental physicist arrived too late to afford him any
satisfaction. Instead it was rather his wise administration of the newly established
Smithsonian Institution that made him famous.
Joseph Henry was born in Albany, the state capital of New York,
on December 17, 1797. His father William Henry was a sometime day
labourer from Argyle, distantly related to the earls of Stirling, while his
mother Ann (n ´ee Alexander) was the daughter of a miller. William Henry
died young, and it was chiefly his widow Ann who brought up her son.
She was a small woman with delicate, rather beautiful features, who lived
126 From Ohm to Helmholtz
to an advanced age. She was a devout and strict member of the Scottish
Presbyterian Church, the principles of which she passed on to her son. Before
he had turned six she sent him to nearby Galway to live with her stepmother
and her twin brother John. After three years of elementary school Joseph got
a job in a general store, where the storekeeper, an educated man, encouraged
him to continue with his education after work. When the boy was
approaching fourteen he returned home to Albany, where he was apprenticed
to a watchmaker and silversmith. After the business had failed he
was released from his apprenticeship, but not before he had acquired some
practical skills that were to be useful to him later.
Although Albany was not a large place in those days, it boasted an
unusually good theatre, which for a year occupied most of the young man’s
leisure hours. He belonged to an amateur group for which he acted, produced
and wrote plays. This experience may have helped in later years when he
needed to be an effective public speaker. During this period Joseph Henry
is described as being remarkable for his good looks, delicate complexion,
slight figure and vivacious nature. His lively temperament made him a general
favourite. The town had an excellent school, almost a college, called the
Albany Academy, where Joseph Henry continued his education by attending
night classes in geometry and mechanics, followed by calculus and chemistry,
while supporting himself by working as a private tutor and doing a
Joseph Henry (1797–1878) 127
little teaching. He was inclined towards science, but in the USA the only
career open to a scientist at this time was in medicine.
Albany also possessed a scientific society, the Albany Institute, with
a miscellaneous library of some 300 volumes. Henry obtained the post of
librarian and gave a few lectures to the members, complete with experimental
demonstrations. Meanwhile he was studying the classicM´ecanique
analytique of Lagrange. The versatile young man also led a grading party for
a new highway running from the Hudson River to Lake Erie. His success in
this work brought him offers of similar positions elsewhere, but he turned
them down in favour of the post of professor of mathematics and natural
philosophy at Albany Academy in 1826. This meant that he had to renounce
his earlier idea of becoming a physician, but he had not got very far with
that.
Henry was now on the threshold of the scientific career which was
to bring him such distinction. He would have read Priestley’s History and
Present State of Electricity and might also have been aware of Coulomb’s
work. Perhaps he also knew of Amp` ere’s work and of Volta’s invention of
the battery, as a source of electric current. In any case, Joseph Henry spent
a good deal of his spare time in the useful exercise of repeating the classic
experiments.
A maternal uncle of Henry’s, a successful businessman in Schenectady,
had died and his widow had brought her family to live in Albany. Her
son Stephen was a delicate and sensitive youth, who at the age of eighteen
had graduated from Union College with high honours in mathematics and
astronomy. Since they had similar interests the two cousins saw much of
each other; soon Stephen was also on the faculty of the Academy and later
he would follow Henry to Princeton. Meanwhile Henry had been courting
Stephen’s sister Harriet, and they were married by the end of 1829. They had
six children, of whom two died in infancy and the only son on the threshold
of manhood. The three survivors, Helen, Mary and Caroline, were to
brighten their parents’ declining years. Modest, retiring and understanding,
Harriet furnished a home life into which Henry could retreat from the pressures
of the outside world. She seems to have been an ideal wife for him.
In his thirty-sixth year Henry was appointed to the chair of natural
philosophy at the College of New Jersey, which would become Princeton
University many years later. He started work there in 1832. The college
was at a low ebb, with only about seventy students, but the situation was
beginning to improve and later Henry was to say that the fourteen years
he spent at Princeton were the happiest of his life. When he first arrived
128 From Ohm to Helmholtz
there was general amazement at his appearance: ‘His clear and delicate complexion,
flushed with perfect health, bloomed with hues that maidenhood
might envy. Upon his splendid front, neither time nor corroding care, nor
blear-eyed envy, had written a wrinkle nor left a cloud; it was fair and pure
as monumental alabaster. His erect and noble form, firmly and gracefully
poised, would have afforded to an artist an ideal model of Apollo.’
One advantage of the move to Princeton was that it brought him into
contact with a wider circle of men engaged in scientific research. No longer
was he obliged to work in an intellectual vacuum. For example, a short
journey on the newly opened railroad brought him to Philadelphia, seat
of another university and home of several learned societies. One of them
was the American Philosophical Society, to which he was elected in 1835.
It was to the members of this society that he communicated the results
of his Princeton researches. Unfortunately the society was rather slow in
publishing papers presented to it, so Henry was continually at a disadvantage
in the competition with Faraday, who took no interest in what was being
done in America.
It is interesting to compare the lives of Henry and Faraday. The
former was born in 1791 and died in 1863, the latter was born in 1797
and died in 1878; but their periods of peak productivity were almost identical.
They both sprang from the same working class that had no traditions
of study and that did not possess the means of educating its children. Both
were influenced to follow a scientific career by the chance reading of books
that revealed the works of nature to the imagination. They were both deeply
religious men who regarded nature as the handiwork of their Creator. However,
no comparison of the two would be complete without reference to
their relative situations at this stage of their careers. We have seen Henry
at work in a small town, with only very little spare time, hampered for
want of funds and facilities, with very few technical companions. Faraday
was much more favourably situated at the Royal Institution, living in the
world centre of intellectual activity, with as much time as he wanted for
research, in constant communication with some of the most brilliant technical
minds of the day. Henry found that his discoveries were anticipated by
Faraday over and over again; he became understandably disappointed and
discouraged.
In 1836, in recognition of his work during his first four years at Princeton,
the trustees of the college granted Henry a year’s leave of absence on
full salary. It was a good time to escape from the USA, for the nation was just
entering upon a financial depression. England by then was in many respects
Joseph Henry (1797–1878) 129
a different country from the one against which the American colonists had
rebelled. Reform was in the air, and the spirit of industry had taken a firm
grip on the people. Although London was his destination, Henry began his
journey by first going toWashington, to collect some letters of introduction;
he was not impressed by the federal capital, where he was destined to spend
so much of his life.
Once in London Henry lost no time in visiting the Royal Society and
the Royal Institution. Unfortunately it was the Easter vacation and Faraday
had just left town, but they met before long, and Henry heard Faraday
lecture. After two useful and enjoyable months, he moved on to Paris for two
more weeks. Observing the passing scene, he found many Gallic customs
curious and was struck by the way women were engaged in many occupations
followed only by men in America. He deplored the prevailing military
spirit, particularly the obligation for every able-bodied male to serve one day
each month on military duty. After brushing up his French, he met a few of
the French men of science and attended a meeting of the Paris Academy, but
otherwise he seems to have made little real contact with the leading French
scientists. Finally, after a short visit to the Netherlands, he returned to
London to stay with his former student Henry James, father of the psychologist
William and of the well-known novelist.
Both Joseph and Harriet being of Scottish descent, like so many New
Englanders, they took the packet to Edinburgh and called on many of the
notables there as well as elsewhere in Scotland. He ended his tour in
Liverpool, where the meeting of the British Association was in progress. On
his return to America, Henry felt well informed about the state of physics
in Europe, especially experimental physics and the teaching of science. He
came back in excellent form, strong and fervent, charged with enthusiasm to
resume his own investigations into electromagnetism. For ingenuity, completeness
and novelty in the examination of new phenomena, these next
researches serve as a model for the experimental physicist. Their significance
lies not so much in the material which he added to science as in the
new territories he opened to the view of those who followed in his footsteps.
Henry had now reached his forty-ninth year. All the high promises
that had accompanied him to Princeton had been fulfilled in the fourteen
years he spent there. He had found congenial companions and duties
well suited to his powers. He had been valued and honoured by members
of the faculty, while the students held him in reverence. Although far
from exhausted scientifically, rather at the height of his powers, he chose
to withdraw from active scientific work and become an organizer and
130 From Ohm to Helmholtz
administrator. The occasion which brought about the change was his decision
to accept the post of secretary to the Smithsonian Institution. With
complete philosophical detachment he had evaluated the needs of American
science and threw in his lot with the new venture to promote the satisfaction
of those needs.
To understand how it came about that a man who was not American
and had no connection with the USA should have founded this great
American institution, it is necessary to say something about the life of the
founder. James Smithson, known in his youth as James Lewis or Luis Mace,
was the illegitimate son of Hugh Smithson, first Duke of Northumberland
of the third creation, and the wealthy and high-born Elizabeth Mace. He
was born in France in 1765, matriculated at Oxford University as a member
of Pembroke College at the age of seventeen and early displayed a taste for
science that never left him. After having been admitted as a fellow of the
Royal Society in 1787, he read papers to that body and published a number
of them, chiefly on chemistry and mineralogy. He already knew most of the
notable men of science of his time, such as Arago in Paris and Cavendish in
London. He spent most of his later life on the continent of Europe, associating
with the men of science in Berlin, Paris, Rome, Florence and Geneva,
but eventually settled in the French capital, although he was in Genoa when
he died. Apparently the reason he left England was that, because of the illegitimacy
and the refusal of his father to acknowledge their relationship, he
never received the social recognition to which he believed he was entitled.
Also perhaps he had too high an opinion of his own abilities and a tendency
to flaunt his wealth.
In his will, made when he turned sixty, Smithson left a life interest
in his considerable fortune to a nephew, after which it should pass to the
‘United States of America, to found at Washington, under the name of the
Smithsonian Institution, an Establishment for the increase and diffusion of
knowledge among men’. Previously he had intended to leave his fortune to
the Royal Society, and it is something of a mystery just why he changed
his mind. After some discussion the bequest was accepted by Congress and
before long over 100 000 gold sovereigns were delivered to New York. Thereupon
there was great debate, extending over nine years, on how precisely
this princely legacy should be used. Eventually it was agreed that there
should be a library, a museum and an art gallery.
At the end of 1845 Henry was appointed secretary and first director
of the new institution. He took up office within days. Most of his
friends advised him against moving to Washington, pointing out his lack of
Joseph Henry (1797–1878) 131
experience in administration and organization, and Henry himself felt no
great enthusiasm about accepting the appointment, recalling the case of
Newton, who made no discoveries after becoming Warden of the Royal
Mint. The Princeton authorities promised him that they would welcome
his return if he decided he had made a mistake. His intentions were of the
best, but it soon became all too clear that members of Congress were going
to interfere and create problems. His immediate problem was to prevent the
capital of the endowment being plundered, for example on a grandiose building,
through the over-ambitious plans of Congressmen. Almost at once he
was offered a chance to escape when he was offered a chair at the University
of Pennsylvania; although this was probably the most desirable scientific
position the country had to offer, ideal for his needs, he turned it down,
greatly to the loss of science, as he did subsequent offers. Henry hoped that
he would be able to return to experimental work once the Smithsonian got
under way, but that was never a real possibility.
Before long the many-turretted red sandstone building in vaguely
Romanesque style known as the Castle was under construction, on a site
in the Washington Mall close to malodorous water and far from the residential
area of the city. Henry began to organize a series of publications
and a system of exchanges with other institutions that enabled the library
to develop. The subjects in which he took an interest are bewildering in
their variety. For some, such as meteorology, he was enough of an authority
himself, but for others, such as zoology, he consulted outside experts.
Increasingly the federal government used the Smithsonian as an all-purpose
institution, for example in designing the land surveys and expeditions which
were so necessary for the exploration of the American continent. Advice was
freely given when telegraph lines were being laid or railroads being planned.
Neither was the work confined to the USA. Today the Smithsonian Institution
comprises the largest complex of museums and art galleries in the
world.
The family, consisting of Joseph, his wife and the three daughters,
lived in the Castle itself, where they entertained liberally. The building
was badly damaged by fire in 1865 and much valuable material destroyed,
including Smithson’s voluminous papers and mineralogical collection, as
well as Henry’s correspondence and research notes. After the end of the
American Civil War he made another visit to Europe with his daughter
Mary. He continued in his various offices until the age of eighty and was
still at work at the end of 1877 when he found one morning that his right
hand was paralysed. Nephritis, in those days incurable, was diagnosed, and
132 From Ohm to Helmholtz
he knew that he did not have long to live. Joseph Henry died in his sleep in
Washington on May 13, 1878 and was buried in the Rock Creek cemetery
in Georgetown. A bronze statue by William Wetmore Story, which stands
at the entrance to the Castle, was unveiled in 1883.
Henry played an active part in establishing the American Association
for the Advancement of Science, which dates from 1848. Fifteen years later
he became one of the original members of the National Academy of Sciences,
an exclusive body like the European academies, which was founded by
President Lincoln to provide technological advice during the Civil War.
Although Henry was regarded as the foremost physicist in his own country,
he found it difficult to understand why his work met with so little approbation
abroad. He missed the fame his discoveries warranted through not
publishing the results of his experiments in time; and when he reformed
his dilatory habit and became punctual in announcing his results, he
still remained inconspicuous because the vehicle he chose was relatively
unknown in Europe. By the time the international scientific world had
awakened to a recognition of his merit, he was already dead.
Hermann von Helmholtz (1821–1894)
Helmholtz was among the most versatile of nineteenth-century scientists.
He was both a physiologist and a physicist. He is famous for his epochmaking
researches on the physiology of the eye and ear, and he is also
famous for his definitive statement of the first law of thermodynamics.
Hermann Ludwig Ferdinand Helmholtz, to give him his full name, was
Hermann von Helmholtz (1821–1894) 133
born in Potsdam on August 31, 1821. His father, August Ferdinand Julius
Helmholtz, had served with distinction in Prussia’s war of liberation against
Napoleon and, after studying at the new University of Berlin, became a
senior schoolmaster at the Potsdam gymnasium, teaching German, classics,
philosophy, mathematics and physics. His mother Caroline (n´ee Penne), the
daughter of a Hanoverian artillery officer, was descended in the male line
from William Penn, the founder of Pennsylvania, and on her mother’s side
from a family of French refugees. She was described as being profoundly
emotional and of sharp intellect while excessively simple in appearance.
The future scientist was their eldest son; they had two younger daughters
and another son, Otto, born in 1833, as well as two other sons who died in
infancy.
Helmholtz was a delicate child who early displayed a passion for
understanding how things worked, but otherwise developed slowly. At the
age of seven he began his school education, moving up to the gymnasium in
the spring of 1832. There he made good progress generally but particularly
in the exact sciences, for which there was an excellent teacher. Although he
was keen on physics, he was persuaded by his father, who could not afford
university fees, to take up the study of medicine, entering the Friedrich
Wilhelm Medical Institute of Berlin in 1838. Students at the institute were
entitled to attend lectures at the university; he took full advantage of this
and also studied a great deal on his own. They also received some financial
support in return for a commitment to serve for five years as military surgeons
after they qualified. By 1842 Helmholtz had progressed sufficiently
to be appointed house-surgeon at a hospital and completed his doctoral thesis
on the structure of the nervous system in invertebrates, the histological
basis of nervous physiology and pathology.
The next step in his career was to discharge his obligation to serve as
a medical officer in the army. In 1843 he was appointed assistant surgeon to
the Royal Hussars at Potsdam. His duties with the squadron left him plenty
of spare time, which he devoted to science, for example by studying the
mathematician Jacobi’s great treatise Fundamenta nova functionem ellipticarum
and by continuing research in physiology. By 1847 he was fully
qualified in medicine and became engaged to a young lady of the distinguished
von Velten family named Olga; however, marriage could not take
place until he had secured a permanent appointment.
In July 1847 he revealed himself as a master of mathematical physics
when he unveiled his theory of the conservation of energy at a meeting of
the Physical Society. He was perfectly willing to concede that others had
134 From Ohm to Helmholtz
had somewhat the same idea, but he was the first to formulate the principle
clearly and demonstrate it conclusively by scientific methods. While it was
enthusiastically welcomed by the younger physicists and physiologists of
Berlin, the older scientists almost without exception rejected it. Among the
mathematicians Jacobi was one of those who unhesitatingly proclaimed the
significance of Helmholtz’ work.
In 1848, through the influence of Baron von Humboldt, Helmholtz
was released from the remainder of his military service to become lecturer at
the Academy of Arts and assistant in the Anatomical Museum in Berlin. He
held these positions only briefly, since the following year he was appointed
associate professor of physiology and director of the physiological institute
at the Albertina University of Ko¨ nigsberg, enabling him to marry. The next
year he published the first part of his classic work on measurements of
the time relations in the contraction of animal muscles and the rate of
propagation in the nerve; the second part followed two years later.
Early in 1851 Helmholtz invented the ophthalmoscope, a turningpoint
in the way his work was regarded. This little invention, which took
him only two months to design and construct, made him famous. Being
back in favour with the authorities, from then on he was left free to follow
the promptings of his scientific curiosity. He went off on a tour through the
Swiss Alps to northern Italy, where he was enchanted by Venice, returning
via Trieste and Vienna. En route he took the opportunity to call on the
leading scientists at the places he passed through. On his return he was promoted
to full professor at Ko¨ nigsberg; his inaugural lecture ‘On the Nature
of Human Sense Perceptions’ was a splendid example of his gift for making
difficult scientific problems, close to the frontiers of research, intelligible
to a general audience. This led to his famous physiological theory of colour
vision, based on ideas of Young.
Helmholtz and his wife were happy and settled in Ko¨ nigsberg. They
were cheerful and contented, serious and industrious yet averse to no social
pleasures, so they gradually acquired an agreeable circle of friends, who
shared the interests of both wife and husband. Helmholtz’ wife was a faithful
help-meet and true comrade, who worked and wrote for him. He read aloud
to her the lectures he was going to deliver, so that she might judge how they
would appeal to an educated audience. However, her health, which had long
been a cause of concern, steadily grew worse. The doctors thought that the
cold climate of Ko¨ nigsberg was one cause of her frequent illnesses, so, when
the professorship of physiology in Bonn fell vacant, Helmholtz enlisted the
support of von Humboldt in order to have himself transferred there.
Hermann von Helmholtz (1821–1894) 135
In 1855, when he moved to Bonn, Helmholtz’ great treatise, the Handbook
of Physiological Optics, was completed. It was the culmination of five
fruitful years spent in Ko¨ nigsberg, years of prolific academic work and high
achievement in various branches of science. Just before leaving for Bonn, he
received an invitation from William Thomson, the future Lord Kelvin, to
address the forthcoming meeting of the British Association in Hull. On the
way to Hull he passed through London, where he saw Faraday at the Royal
Institution and George Biddell Airy, the Astronomer Royal, at the Royal
Observatory. ‘Faraday is as simple, charming and unaffected as a child’, he
noted, ‘I have never seen a man with such winning ways.’ At the meeting
he was particularly impressed by the fact that his audience of 850 included
236 ladies. ‘Here in England’, he wrote home, ‘the ladies seem to be very
well up in science.’
Helmholtz soon accustomed himself to life in Bonn, where his wife’s
health improved considerably, thanks to the milder climate. Officially his
duties were to teach anatomy, for which he was certainly qualified but felt
the lack of any previous teaching experience. He also lectured on his main
subject of physiology. In his experimental work he was at first handicapped
by the lack of scientific instruments; he had been able to take only very few
of them with him from K¨ onigsberg and he found practically nothing useful
when he arrived at Bonn. His interests were now turning from the theory of
vision to that of sound. He applied the mathematics of Fourier series, which
led to another classic work, the Theory of the Sensations of Tone.
However, Helmholtz had hardly settled down in Bonn when he
received an invitation to move again, this time to Heidelberg, where he
would be appointed professor of physiology, rather than anatomy. Bonn
attempted to retain him by increasing his salary and promising to improve
the facilities provided for anatomy. He and his wife already had made many
good friends in Bonn. Against this, Heidelberg boasted Robert Bunsen and
Gustav Kirchhoff, two of the leading scientists of the period. Although the
state of his wife’s health made another move undesirable, in the end he
decided on Heidelberg. The Prussians, who governed Bonn, made every
effort to dissuade him, but they succeeded only in delaying the transfer
until 1858, when he joined Bunsen and Kirchhoff to inaugurate the most
glorious age in Heidelberg science.
The Helmholtz family, which now included two small children,K¨athe
and Richard, settled down well in Heidelberg. He was elected a corresponding
member of the Academy of Sciences in Munich and attended its festival
in March 1859, meeting some of the other academicians, as well as the
136 From Ohm to Helmholtz
composer Richard Wagner and King Ludwig II. Meanwhile he received the
news from Potsdam that his father, to whom he was closely attached, had
died following a stroke, while at home it was increasingly clear that the
health of his beloved wife was rapidly declining. She died at the end of the
year, leaving him despondent. He was already suffering from migraine and
fainting fits, brought on by the strain. He sought comfort and distraction
in his work. Further recognition came with corresponding membership of
the academies of Vienna and Go¨ ttingen and the award of the Order of the
Golden Lion from the Netherlands.
The subject of the next profile will be Lord Kelvin. When he was
still just William Thompson, he met Helmholtz for the first time when
he was in Germany in 1855. Afterwards Helmholtz wrote to his wife that
‘I expected to find the man, who is one of the first mathematical physicists
of Europe, somewhat older than myself, and was not a little astonished when
a very juvenile and exceedingly fair youth, who looked quite girlish, came
forward . . . he far exceeds all the great men of science with whom I have
made personal acquaintance, in intelligence and lucidity and mobility of
thought, so that I felt quite wooden besides him sometimes.’
A remarkably close friendship and scientific collaboration sprang
up between Helmholtz and Thompson, which lasted until the death of
Helmholtz, nearly forty years later. In the summer of 1860 he went to stay
with Thomson on the Isle of Arran; and the following February wrote to
him about his plans for the future:
I had seriously to think of introducing a new order of things, and if
this had to be done, it was better it should be soon. In the end it came
about more rapidly than I expected, for when love has once obtained
permission to germinate, it grows without further appeal to reason.
My fianc´ee is a gifted maiden, young in comparison with myself, and
is I think one of the beauties of Heidelberg. She is very keen-witted
and intelligent, also accustomed to society, as she received a good deal
of her education in Paris and London . . . I should never have
presumed, as a widower with two children, and no longer in my first
youth, to seek the hand of so young a lady, who had every
qualification for playing a prominent part in society. However it all
came about very quickly and now I can once more face the future
happily. The wedding is to be at Whitsuntide.
Helmholtz’ second wife, Anna von Mohl, was a woman of great force
of character, talented, with wide views and high aspirations, clever in society
Hermann von Helmholtz (1821–1894) 137
and brought up in a circle in which intelligence and character were equally
esteemed. In 1862 a son, Robert Julius, was born, but this nearly cost Anna
her life and the son soon became fatally ill. Then in 1864 she gave birth to
a daughter, Ellen Ada Elizabeth.
At Easter 1861 Helmholtz made another visit to England, to lecture
on the physiological theory of music, and was prevailed upon to give an
evening discourse at the Royal Institution on the application of the law
of the conservation of energy to organic nature. In 1864 he was back in
England for six weeks, mostly in London but also in Oxford, Glasgow and
Manchester: he lectured at the Royal Society and the Royal Institution and
met the young Clerk Maxwell for the first time. The following year he was
in Paris, returning for the Ophthalmological Congress held there during the
Great Exhibition of 1867.
By 1868 Helmholtz had been in Heidelberg for ten years, and the
Prussians decided to make another effort to secure his return. The chair
of physics and mathematics at Bonn had been left vacant by the death
of Julius Plu¨ cker, which led Bonn to enquire whether Helmholtz would
be interested in returning as professor of physics (Plu¨ cker was unusual in
being well-qualified in both disciplines). In his reply Helmholtz explained
that physics had originally been his principal scientific interest and that
he had been led to medicine, particularly physiology, by force of circumstances.
He went on to say that ‘what I have accomplished in physiology
rests mainly upon a physical foundation. The young people whose studies I
now direct are for the most part medical students, and most of them are not
sufficiently grounded in mathematics and physics to take up what I should
consider the best of the subjects that I could teach . . . Lectures in pure
mathematics I could not well undertake; in those on mathematical physics
I should treat mathematics as the means and not as the end.’ Interestingly,
in 1868 he surprised the scientific and mathematical world by publishing an
essay ‘On the Facts that Underlie Geometry’, which had much in common
with Bernhard Riemann’s masterly paper ‘On the Hypotheses that Underlie
Geometry’, published fourteen years earlier, of which he was unaware, but
there were some differences and even errors in Helmholtz’ work.
In the end Helmholtz decided to remain at Heidelberg. Another son,
Friedrich Julius, was born, but did not thrive. At the beginning of 1870
Helmholtz was elected an external member of the Berlin Academy, and
efforts were now made to interest him in moving to the Prussian capital.
The faculty of philosophy at the University of Berlin had a vacancy to fill,
following the death of Magnus, and proposed to offer it to either Kirchhoff
138 From Ohm to Helmholtz
or Helmholtz, with a preference for the former: ‘if Helmholtz is the more
gifted and universal in research, Kirchhoff is the more practised physicist
and successful teacher. While Helmholtz is more productive, and is always
occupied with new problems, Kirchhoff has more inclination to teaching; his
lectures are a model of lucidity and polish; also from what I hear he is better
able to superintend the works of elementary students than Helmholtz.’ By
all accounts Helmholtz was a poor lecturer, who simply read out verbatim
passages from the books he had written. Despite this, he attracted outstanding
students.
When it became clear that Kirchhoff would not leave Heidelberg,
Helmholtz was invited to state his requirements for taking the Berlin post.
Although the university had been founded in 1810, science was not taught
until later and even then only at an elementary level. Helmholtz was determined
to make Berlin a major centre for physics. He asked for an institute
of physics, with the necessary equipment, of which he would be director,
and an official residence. The Minister of Education agreed to his terms
and the Helmholtz family prepared to move. Confirmation of the appointment
was held up until the end of the year, because of the Franco-Prussian
War. Almost immediately afterwards he received a letter from Sir William
Thomson asking whether he would be willing to accept the chair of experimental
physics in Cambridge, but by then Helmholtz felt committed to
Berlin.
Helmholtz and his wife Anna entertained in great style. Their parties
brought together intellectuals, scientists, artists and leaders of both government
and industry. Their daughter Ellen married the son of the great
industrialist Werner von Siemens. The two children by Helmholtz’ first
marriage had been, since his second marriage, in the care of their grandmother.
The daughter K¨athe grew up a serious woman, greatly loved and
admired but never satisfied, a gifted artist who painted in the ateliers of
Berlin and Paris. She spent a year in France and England. After she had
married in 1872 a daughter was born, but then her health declined and she
died five years later. Helmholtz’ eldest son Robert volunteered for military
service and was sent to the front where he was accidentally injured; after
discharge from the army he became a student at the Munich polytechnic
before embarking on a successful career in mechanical engineering.
In 1871 Helmholtz was back in Britain again for the meeting of the
British Association at Edinburgh, meeting beforehand the mathematical
physicist P.G. Tait and the naturalist T.H. Huxley at St Andrews. Later
he joined SirWilliam Thomson, by this time Lord Kelvin, for a cruise on his
yacht. Helmholtz was struck by Kelvin’s easy relationships with students,
Hermann von Helmholtz (1821–1894) 139
engineers, seafarers and aristocrats. The sea was rough, but this was not
allowed to interfere with scientific work.
In 1876, although he had only been there for five years, he was elected
rector of the university; in his inaugural address he particularly praised the
academic freedom enjoyed by German students and faculty, ‘which amazes
all foreigners’. At the end of his year of office he went on a tour of Italy,
seeing various scientists en route, and in 1880 made a similar tour of Spain.
The next year he went to London, accompanied by his wife Anna, to give
the Faraday lecture at the Chemical Society and then on to Cambridge to
receive an honorary degree. In Germany he was elevated to the ranks of the
hereditary nobility and so became entitled to use the prefix ‘von’.
In 1887 he was appointed president of the new physical–technical
institute at Berlin Charlottenburg, which had been established through the
munificence of his friend Werner von Siemens. During the next few years
Helmholtz was much involved in the work of setting up the new institute.
Although he retained his position at the university, he was relieved of many
of the routine duties attached to it. He crossed the Atlantic for the first time
on the occasion of the Chicago World’s Fair; his wife, who went with him,
had serious misgivings about the wisdom of making the journey. They were
impressed by the cities of the east and by Niagara Falls, but not by the
prairies; they went as far west as the Rockies. Felix Klein, who was with
them, wrote an account of what happened on the voyage back to Europe:
‘we were sitting in the smoking room till about 10 p.m. with a perfectly
calm sea . . . when Helmholtz, remarking that it was time to go to bed, went
down a fairly steep stairway leading to the saloon. Then we heard a heavy
fall . . . on which we all hurried below, and were in time to see Helmholtz
lifted by a number of stewards at the foot of the gangway, and carried into
his cabin; there was a pool of blood on the floor.’ His wife Anna, who was
suffering from sickness at the time, wrote to the children:
Professor Klein came in, and broke to me that your father had fallen
down the companion way, and was bleeding from the forehead and
nose, and that two doctors were with him; and he led me into the
ship’s doctor’s cabin. There lay your father covered with blood, but he
appeared to be conscious and was able to answer all questions. At first
they feared an apoplectic stroke, which I never believed for a moment,
but I think one of his old and long-forgotten swoons must have
suddenly come over him. Evidently he had become unconscious before
the fall, since he did not put out his hands to protect himself but fell
heavily on his face.
140 From Ohm to Helmholtz
Helmholtz gradually recovered from the accident, but he was weakened
by it and suffered from double vision and vertigo. There were other
shocks in store; the death of his beloved son Robert, the constant illness in
mind and body of his invalid son Fritz and then the untimely death of his disciple
Heinrich Hertz, a great loss to science. Nevertheless, Helmholtz was
able to carry on both his scientific research and his administrative duties
at the institute until, on July 12, 1894, he experienced a stroke, which left
him confused and partially paralysed. His condition gradually deteriorated
until the end came in his seventy-third year on September 8, 1894. His wife
survived him by five years; their son Fritz died in 1901, at the age of 33.
The enormous influence Helmholtz wielded derived from his magnetic
personality. The notoriously reticent and undemonstrative physicist
Max Planck gives us some idea of how impressive this was:
In his whole personality, his incorruptible judgement and in his
modest manner he represented the dignity and truth of science. I was
deeply touched by his human kindness. When in conversation he
looked at me with his quiet, searching but benevolent eyes, I was
seized by a feeling of boundless, childlike devotion. I would have been
prepared to confide in him anything which affected me deeply in the
certainty of finding in him a just and mild counsellor, and an
appreciative or even praising word from his mouth gave me greater
happiness than all the success I could achieve in this world.