3 From Rumford to Oersted
Our third five remarkable physicists were born in the twenty-five years from 1753
to 1777. Two came from France and one from each of America, England and
Denmark.
Sir Benjamin Thompson (Count Rumford) (1753–1814)
We return to America for our next profile. It is impossible to give a full
account of all the twists and turns of the picaresque life of Benjamin
Thompson in just a few pages. A convenient starting-point, for our purposes,
might be his arrival in London in the summer of 1776, when he was
already twenty-three; except that the early years of his life are significant for
what came later, so at least an outline is essential. Like Benjamin Franklin
he was born in New England, of humble parents, and spent part of his career
in America, part in Europe. However, Thompson and Franklin had very different
characters and whereas Franklin became a leading American patriot,
Thompson did not.
The future Sir Benjamin Thompson, Count Rumford, was born
Benjamin Thompson at Woburn, Massachusetts, on March 26, 1753; his
parents Benjamin and Ruth (n´ee Simonds) were farmers in a small way.
Owing to a boundary dispute, the same place was also known as Rumford
(now Concord), New Hampshire, whence the title he took later on in life. In
boyhood he early showed an inclination towards science. He was naturally
skilful in drawing, lettering and mechanical techniques, as well as ingenious
in the arrangement of the meagre apparatus at his disposal, and he devised
experiments in electrostatics, chemistry and mechanics. His interest in the
laws of nature extended to astronomy and, at the age of fourteen, he was
able to predict the time of occurrence of an eclipse. From a local doctor
with whom he boarded for a while he learned the rudiments of medicine
and surgery. Through the acquaintance of a mutual friend, Loammi Baldwin,
late of the colonial forces in the French and Indian War, young Thompson
attended lectures at Harvard College given by the celebrated professor
John Winthrop. Thompson and Baldwin learned from each other, in a selfimprovement
society of two. They tried to repeat Franklin’s experiment of
Benjamin Thompson (Count Rumford) (1753–1814) 75
flying a kite during a thunderstorm but merely ‘felt a general weakness in
their joints and limbs and a kind of lifeless feeling’. Baldwin went on to
become a prominent civil engineer, but his friend’s career developed quite
differently.
First Thompson made an advantageous marriage with a wealthy
widow, SarahWalker Rolfe, who was considerably older than himself. They
had a daughter, also called Sarah, of whom more later. His wife introduced
him into her social circle, including the Royal Governor of New Hampshire,
on whom he created such an impression that he was immediately offered
a commission as major in the 2nd New Hampshire Regiment. It is thought
that this must have been on the understanding that he would provide intelligence
for the British forces in theWar of Independence. However Thompson
spent the next year or so, he thought it prudent to leave the Boston area when
the city was taken by George Washington. Before long he was on his way
to England, having left his wife and daughter behind; he made no enquiries
after his wife for the next thirty years and none after his daughter for the
next twenty. He contrived to keep his whereabouts secret from them so that
the only way they could get in touch with him was through Baldwin.
When he arrived in London in the summer of 1776 the outcome of
the War of Independence was still in doubt and many American supporters
of the British side were in London expecting that a grateful nation would
provide for them until they could safely return home. They were generally
76 From Rumford to Oersted
disappointed in this, but not Thompson. He had a way of furthering his
fortunes by associating with those in power and before long he had become
a prot´eg´e of Lord George Germain. Germain had been out of favour with
the King and had allied himself with the Prince of Wales. When the Prince
succeeded to the throne he rewarded Germain by making him Secretary
of State for the Colonies, with responsibility for ensuring that the colonial
rebellions were suppressed. Naturally Thompson, as his number two, was
himself in a position to acquire power and influence. He secured the important,
and lucrative, task of equipping and victualling large numbers of British
troops.
Meanwhile he was developing a reputation in other ways. His interests
extended to military affairs, social reforms, animal husbandry and horticulture;
to each of these fields he applied the rigour of the experimental
scientist. From the very first months of his residence in England he used his
powers of observation to devise ways and means for the promotion of human
comfort and safety; in the economical use of fuel, the better designing of
chimneys and the more efficient use of firearms. This was technology rather
than science, but he was applying his scientific knowledge, as he was later
when he conducted experiments on ballistics. It was these activities that
led to his election to the Royal Society in 1780, at the age of twenty-seven.
After Germain had fallen from power, Thompson, never backward in
looking after himself, decided to move on. Sensing that the British cause
was lost in America, he returned to New York, where he was temporarily
given command of a Republican regiment. After returning to London
Thompson decided, on the strength of some limited military experience
acquired in America, to purchase a colonelcy; at this time commissions in
the British army were available for purchase, although influence was also
useful. He then set out for the continent in search of employment as a soldier
of fortune. Karl Theodor, the Elector of Bavaria, was an old-style ruler
who was looking for a scientist to ornament his court, and, when Colonel
Thompson presented letters of introduction and offered his services, the
Elector decided that he might be valuable both as a scientist and in a military
capacity. Permission from London for him to enter the service of the
Elector being forthcoming, together with a quite unexpected knighthood,
Sir Benjamin, as he was now entitled to call himself, set out to make himself
useful.
Among the services he provided for Karl Theodor was the clearance
of beggars from the streets of the capital. Bavaria was a poor country and
poverty was widespread. Rumford’s solution was to use the army to force
Benjamin Thompson (Count Rumford) (1753–1814) 77
the beggars into purpose-built workhouses, where they were confined and
set to work making military uniforms in return for their subsistence. This
was characteristic of Rumford’s attitude to social problems. Another service
was the construction of the ‘English Garden’, a popular feature of Munich to
this day. This was an attractive park laid out along the Neckar by the army
for the Elector but open to the public. The grateful Karl Theodor heaped
appointments on him; by 1790 he was privy councillor, major general of the
cavalry and adjutant general; two years later he was also lieutenant general
of the artillery, chief of staff and chief of the general staff. In 1791 the Elector
conferred on him the title of Count, amongst other honours, and from now
on we may refer to him as Count Rumford.
In Munich Thompson had two mistresses, who were sisters. The
older, Countess Baumgarten, was plump and buxom, a celebrated beauty
whose concurrent intimacy with Karl Theodor proved most useful to
Thompson. She bore him a daughter, Sophia, who was raised as a Baumgarten
child. The younger sister was Countess Nogarola. She was a slim,
athletic-looking woman with a strong intelligent face, who was not particularly
beautiful but whose keen mind and intellectual interests were quite a
match for Thompson’s own. They were intimate friends for many years. She
helped him with his correspondence in French and German and translated
some of his writings into Italian.
Meanwhile Rumford still found time for scientific work. The theory
of heat and its applications were his speciality; and he helped to undermine
the old caloric theory. His most important discovery was that a limitless
amount of heat can be produced by friction, which was conclusively
demonstrated in the cannon foundry of Munich, where the boring of gun
barrels produced large quantities of heat. He was a careful and methodical
experimenter, although the far-reaching implications of the results he had
obtained were not fully appreciated at the time.
In March 1793 London heard that ‘General Count Rumford’ had
obtained leave from the Elector to go to Italy for the sake of his health. Just
before leaving he heard from his American daughter Sarah that her mother
had died and Baldwin had revealed her father’s whereabouts to her. A young
American then arrived in Munich to ask for Sarah’s hand in marriage; he
was promptly sent away. Rumford then went off to Italy, first to Milan and
Pisa, then to Pavia, where he had some scientific contact with Volta, and
finally east to Verona, where his beloved Countess Nogarola lived with her
children. After some months in that area he went down to Florence, where
he had an affair with Lady Palmerston, who was then on the Grand Tour
78 From Rumford to Oersted
with her husband, and met her again in the south of Italy. After a year away
he began the return journey, stopping for several months with Countess
Nogarola en route.
After a year back in Munich Rumford found that life there was becoming
increasingly unpleasant. As his political power grew, so did persistent
rumours of mismanagement and self-aggrandizement; he reacted in a most
vindictive manner to those who opposed him. He persuaded the Elector to
grant him six months’ leave to go back to London to oversee the publication
of his new scientific work. He set out in October 1795, but, when
he arrived in London, a large trunk, containing ‘almost all the papers of
any consequence I possess in the world’, was removed from his carriage by
thieves. Although he lost all his scientific papers, probably what the thieves
were after was his private papers, which might have been useful to his
enemies. Rumford soon discovered that he was a political and social outcast
in London. He settled down to rebuilding his reputation in the capital and
publishing his scientific work. He wanted someone to look after him and
thought of his long-neglected daughter Sarah, with whom he had become
reconciled. He invited her to come over and join him. How he thought a
daughter he had abandoned years before in a New England village could
suddenly be transported to the fashionable salons of London and be an ornament
to society is hard to understand, but, if this is what he expected, Sarah
was a disappointment to him, as he was to Sarah. After a month he put her
into a fashionable girls’ school to learn the manners and etiquette of London
society.
Meanwhile Karl Theodor’s troubles had escalated. To go back some
years, when the Elector Maximilian II of Bavaria died in 1777, the junior
line of the Wittelsbachs, which had ruled that country for four and a half
centuries, became extinct. As Elector Palatine of the Rhine, Karl Theodor,
head of the family’s senior branch, was expected by virtue of arrangements
of long standing to inherit the Bavarian electorate and thereby reunite the
two Wittelsbach fiefs. This was acceptable to Austria only on conditions
that were unacceptable to Frederick the Great in Berlin, but in the end
Karl Theodor succeeded to the Munich throne and Bavaria lost some territory
to Austria. By 1792, however, Karl Theodor found himself threatened
not only by Austria, which remained dissatisfied, but also by the French
revolutionary armies. The latter overran the Palatinate and in 1795 invaded
Bavaria itself. The Elector, trapped between the forces of France and Austria,
appealed to Rumford to return from London and prepared to take refuge in
Saxony.
Benjamin Thompson (Count Rumford) (1753–1814) 79
Rumford arrived, accompanied by his daughter Sarah, just before Karl
Theodor fled to Dresden, and began by rallying the Bavarian troops. Thanks
to his knowledge of large-scale cooking and to his improvements in the
design of boilers and stoves, as well as his skill in conserving fuel, Rumford
was able to provide cheaply and comfortably for the large numbers of soldiers,
at first scattered and disorganized, who had converged on Munich to
be lodged and fed. When the Austrians tried to use Munich as a base from
which to resist the French, Rumford, with his customary firmness, tact and
presence of mind, managed to persuade both the invading armies to refrain
from molesting that city. This was no small achievement.
Rumford had served Bavaria in many capacities. On his return to
Munich, Karl Theodor offered him one more appointment, as head of the
General Police, but Rumford preferred to go back to Britain. The Elector
sought to honour him by designating him as his ambassador to the Court of
St James, and, under this supposed assignment, Rumford returned to London
in 1798. However, the count, as Sir Benjamin Thompson, was already a
British subject and could not therefore serve as a representative of a foreign
power, be it ever so friendly.
Rumford was by this time a wealthy man. After a long absence he
was able to mingle once again with his many friends and admirers in the
scientific world of the city, drawing their attention to the measures of
public and domestic economy which had made him famous in Germany.
He was welcomed on all sides for his ingenuity and philanthropy. Both the
Royal Academy and the Society for the Encouragement of Arts and Manufactures
(later the Royal Society of Arts) elected him to honorary membership.
In 1792 he had been awarded the Copley medal by the Royal Society for
‘various papers on the properties and method of communication of heat’.
Possibly through a desire to emulate Sir Godfrey Copley and hence perpetuate
his own name in the British scientific world, Rumford wrote to the Royal
Society in July 1796 offering ‘a fund of one thousand pounds, the interest on
which would be spent every second year as a premium to the author of the
most important discovery or improvement in the subjects of heat and light,
especially those applications which would contribute most to the good of
mankind’. The offer was accepted and the dies for a Rumford medal ordered
and made. Rumford himself received the first such medal in 1802.
Although the impossibility of serving as the Bavarian ambassador in
London was at first a severe blow to Rumford, he did not let himself remain
idle for long. His active mind turned towards a project that would afford
at once activity and, he hoped, advancement. His interests now centred
80 From Rumford to Oersted
themselves on a philanthropic organization that was at that time attracting
public notice, the Society for Bettering the Condition and Increasing the
Comforts of the Poor. One of its leading members wasWilliamWilberforce,
anti-slavery leader and prominent evangelical layman in the Church of
England. What this praiseworthy society was trying to do for the lower
orders of population by lessening their misery in one way should, in the
opinion of Rumford, be augmented by efforts towards increasing the efficiency
of their labours, for example by improving their mechanical skills.
Acting with the support of the society, Rumford drew up plans ‘for
forming by subscription, in the metropolis of the British Empire, a public
institution for diffusing the knowledge and facilitating the general introduction
of useful mechanical inventions and improvements, and for teaching by
courses of philosophical lectures and experiments the application of science
to the common purposes of life’. A committee chaired by Sir Joseph Banks
was formed, and the outcome was the Royal Institution of Great Britain,
which was incorporated on January 13, 1800 and granted a Royal Charter
by George III. Since the Royal Society had no laboratory facilities itself, it
became customary for its fellows to turn to the Royal Institution if there
were experiments they wished to see performed. Later it was often described
as ‘the workshop of the Royal Society’.
With characteristic enthusiasm and passion for details, Rumford
threw himself into the organization of the new institution. A building in
Albemarle Street was purchased and remodelled according to his plans –
complete with lecture room, repository for models, workshops and kitchens.
In order that possible patrons might not feel left out, Rumford engaged professors
and lecturers to provide scientific instruction for those of the upper
classes who might care to keep abreast of the times. Committees were set
up to suggest and supervise research in science and the useful arts. The programme
included a school for mechanics and a print shop for the publication
of research articles. It seemed as though every one of the count’s gamut of
interests, save the military, was wrapped up in this new socio-scientificphilanthropic
institution
For the educational programme the services of Thomas Young were
secured; his profile is given later. Unfortunately he was too erudite to make a
good lecturer for popular audiences, but his colleague Humphrey Davy made
up for this. Davy, who was already renowned for his discovery of the benefits
of nitrous oxide as an anaesthetic, was appointed assistant lecturer in
chemistry, director of the laboratory and assistant editor of the publications
of the Institution. He was allowed to occupy a room in the house, which was
Benjamin Thompson (Count Rumford) (1753–1814) 81
furnished with coals and candles, and paid one hundred guineas per annum.
His lectures drew large crowds, for he had a natural gift for making science
interesting to the layman and could hold his audiences by the infection of
his own enthusiasm. What he started soon became the chief characteristic
of the Royal Institution – a well-balanced combination of scientific research
and the exposition of its results in the lecture theatre.
Unfortunately the entire scheme was altogether too ambitious. The
institution could not be financially self-supporting, at least not in its early
days. Rumford, with his care for details and rigorous attitude towards the
fulfilment of his plans, could not cope with the situation he had created.
Once he was out of the country, some of his pet schemes were abandoned
on the grounds of economy. The school for mechanics, the culinary demonstrations
and the workshops for model-makers were soon discarded. On
reflection, education of the masses seemed less important than the popularization
of science among the upper classes. Of course all strata of the
population were welcome to visit the rooms and workshops, but the times
were not ripe for the establishment of trade schools.
When Rumford returned to Munich, he was pleased to see his natural
daughter Sophia Baumgarten had grown into a charming young lady.
However, the pleasures of his stay in Bavaria were eclipsed by his flattering
reception in Paris, his next port of call. He was presented to Napoleon
as a Bavarian general; the First Consul took an immediate liking to him,
showering him with special attention. He stayed altogether two months
in the French capital, sending reports to London and Munich on politics,
to Lady Palmerston on the social life and to Sir Joseph Banks on science
and scientists. As for Napoleon: ‘Bonaparte is a person endowed with very
uncommon abilities. And the more I see of him, and the more I consider
the wonderful things he has done, and is doing, the more I am disposed to
admire his genius, and to give credit to the wisdom of his plans, and the
purity of his intentions.’ Napoleon made great use of natural philosophers,
and Rumford as a famous visiting scientist found that he had an immediate
entr´ee to the highest political circles. He met Lafayette and Talleyrand,
dined with Berthollet, was introduced to Laplace, attended a session of the
Paris Academy and was elected to membership in two different classes,
namely the one dealing with mathematics and physics and the one dealing
with political economy. Most of all he was f ˆeted by the Parisian ladies.
When he returned to London Rumford found that the king ignored
him, while Lady Palmerston, offended by his glowing accounts of the ladies
of Paris, would not receive him. He tried to sort out the problems at the
82 From Rumford to Oersted
Royal Institution, which was already in financial difficulties. Unfortunately
differences kept arising between Rumford and the management of the institution,
which became so acute that he left London in May 1802, vowing
never to return. He again went first to Munich and then on to France. By
this time Napoleon’s campaigns were redrawing the map of Europe, and
England was targeted. Napoleon no longer singled him out as a person of
importance, never once spoke to him privately.
It was quite natural that the brilliant salons which Madame Lavoisier,
the widow of the great chemist, held regularly at her home in Paris would
attract a scientist of Rumford’s stature. A veritable galaxy of scholarship
was represented at these gatherings, not only French scientists such as
Arago, Berthollet, Biot, Lagrange and Laplace, but also scientists of other
nationalities, such as Charles Blagden, who courted her unsuccessfully,
and the famous Baron von Humboldt. Rumford’s international reputation,
together with his courteous manner and interests so akin to those of her late
husband, could not fail to impress the vivacious and yet serious-minded lady.
She was no doubt impressed by her new guest’s account of his work for the
poor of Bavaria and his improvement of the living conditions of the indigent
of London.
Marie Anne Pierrette Paulze had married Lavoisier when she was
thirteen years old. For the twenty-three years they lived together she acted
as his research assistant, librarian, collaborator and scientific confidante.
She was a gracious hostess to their constant flow of visitors, both French
and foreign, and, being the better linguist, translated papers for him. She
knew enough chemistry to edit and publish his great M´emoires de chimie,
which had been left in a very fragmented format the time he was guillotined
for being farmer-general in the oppressive taxation system. She continued
to be famous for her social events: a formal dinner party every Monday, an
‘at home’ every Tuesday, a musical soir ´ee every Friday. She was now 43 and
had been a widow for nine years, Rumford was 50 and had been a widower
for eleven. Before long their marriage was celebrated.
Sarah, who had returned to America in 1798, had not been told by her
father of this impending development until he wrote to her early in 1804:
‘I shall withhold this information from you no longer. I really do think
of marrying, though I am not yet absolutely determined on matrimony.
I made the acquaintance of this very amiable widow in Paris, who, I believe,
would have no objection to having me for a husband, and whom in all
respects would be a proper match for me. She is a widow, without children,
never having had any; is about my own age, she enjoys good health, is very
Benjamin Thompson (Count Rumford) (1753–1814) 83
pleasant in society, has a handsome fortune at her own disposal, enjoys a
most respectable reputation, keeps a good house, which is frequented by the
first philosophers and men of eminence in the science and literature of the
age, or rather of Paris. And what is more than all the rest, she is goodness
itself . . . she has been very handsome in her day, and even now at 46 or 48
is not bad looking; of a middling size, but rather en bon point than thin. She
has a great deal of vivacity and writes incomparably well.’
Rumford made another brief visit to Munich, where little had
changed. Madame Lavoisier came out to join him and together they returned
to Paris via Switzerland. She went on ahead of him to ensure that he would
be allowed into France, because by this time England and France were at
war again. They were married on October 24, 1805 and settled into a house
in the rue d’Anjou close to the Tuileries Gardens and the Champs Elys´ ees.
It cost 3000 guineas and was set in a beautiful two-acre garden. She decided
that she wished to be known as Countess Lavoisier de Rumford. Rumford
seemed to be very happy and he wrote to Sarah saying that ‘he had the best
of pinned hopes of passing my days in peace and quiet in this paradise of
a place’. However, before long she learnt that all was not well with the
new marriage. Although they had known each other for almost five years,
they soon discovered that they were incompatible and started arguing about
almost everything. The countess liked entertainment and small-talk, but
he preferred quiet contemplation and experiment. She liked good food and
wine, but his stomach could not take it, so he generally sat at a separate
small table when they had guests. He loved music but she did not care for
it. Most of all she objected to the way he kept altering the house and its
contents to suit his own tastes without any reference to hers.
Two months after the marriage he was writing to Sarah that, ‘between
you and myself, as a family secret, I am not at all sure that certain persons
were not wholly mistaken in their marriage, as to each other’s characters’.
At the end of the first year: ‘very likely she is as much disaffected towards
me as I am towards her. Little it matters with me, but I call her the female
dragon.’ On the second anniversary: ‘I am still here, and so far from things
getting better they get worse every day. We are more violent and more
open in our quarrels’. Things went from bad to worse. In April 1808 he
wrote to Sarah, describing his wife as the most imperious, tyrannical and
unfeeling woman that had ever existed, whose perseverance in pursuing an
object was equal to her profound cunning and wickedness. He said that he
could not call her a lady, that it was impossible to continue and spoke of
separation.
84 From Rumford to Oersted
Rumford had tired of social events and talking with people when he
would rather have been working on his essays or in his garden. She was
annoyed by his ceaseless alterations to their house, and there was friction
between the German servants he brought from Bavaria and her own,
who were French. Although they tried to make a success of the marriage,
after nearly four years of endless quarrels, some violent, it was annulled by
mutual consent. Countess Lavoisier de Rumford returned to her round of
salons while the count retreated to a property at Auteuil near the Bois de
Boulogne. Here he resided for the remainder of his days, devoting his energies
to arranging, beautifying and improving the grounds. He paid a final
brief visit to Munich, where he learned that Countess Nogarola had died
and Sophia, his illegitimate child by her sister, was very ill. He summoned
Sarah to Paris to keep him company. She arrived late in 1807, bringing the
news that his old friend Baldwin had died. She was pleased to see her father
so contented with his fine garden, string of lively horses and songbirds in the
dining room. He had renewed his scientific interests and began to frequent
the Paris Academy again. He was still on speaking terms with his ex-wife,
whom Sarah found very charming: ‘it was a fine match, could they but have
agreed’.
Sarah was with her father at the last, acting as his hostess when he
invited some of his old associates in the sciences to dine with him and discuss
some of the problems at the Royal Institution. There was also another
mistress named Victoire Lef`evre, who bore him a son, named Charles
Franc¸ois Robert Lef`evre, and it was his son, Rumford’s grandson, who succeeded
to the title in due course. Rumford appeared to be in good health,
but on August 21, 1814 he died suddenly of ‘a nervous fever’. The funeral,
which took place at the cemetery at Auteuil three days later, was a lonely
affair with only a handful of people at the graveside. He left the residue
of his estate to Harvard University to establish a Rumford Professorship,
which still exists. Its purpose is ‘to teach by regular courses of academical
and public lectures, accompanied by proper experiments, the utility of the
physical and mathematical sciences for the improvement of the useful arts,
and for the extension of the industry, prosperity, happiness and well-being
of society’.
In his declining years Rumford had lost most of his old friends and
made hardly any new ones. The generally accepted view is that this was
because he was an insufferable genius who treated people with whom he
had to work with such disdain and contempt that he simply made more and
more enemies as he grew older. One commentator wrote that ‘he was utterly
Jean-Baptiste Fourier (1768–1830) 85
devoid of humour and humanism; hard, brittle and self-centred to the last’.
Another wrote that he was ‘unbelievably cold-blooded, inherently egotistic
and a snob’, and yet another that ‘he was the most unpleasant personality
in the whole of science since Isaac Newton’.
After her father’s death Sarah stayed on at Auteuil until May 1815 but
thereafter moved between London and Paris until she returned to Concord
to end her days and died in 1852 in the very room where she had been born
seventy-nine years before. When asked about her father she would say ‘he
was fond of having his own way, even, as I fancied, to despite me’. ‘He could
go one way or the other. And it was invariably the case, that when quiet and
happy himself he was like others or, in other words, agreeable; but when
perplexed with cares or business, or much occupied, there was no living
with him.’
Jean-Baptiste Fourier (1768–1830)
Jean-Baptiste-Joseph Fourier, to give him his full name, is the most illustrious
son of Auxerre, the principal city of western Burgundy, where he
was born on March 21, 1768. Both his father Joseph, a master tailor originally
from Lorraine, and his mother Edmie died before he was ten years
old. Fortunately certain local citizens took an interest in the orphaned
boy’s education and secured him a place in the progressive Ecole Royale
86 From Rumford to Oersted
Militaire, one of a number of such schools run by the Benedictine and other
monastic orders. Science and mathematics were taught there, among other
subjects, and, while the boy displayed all-round ability, he had a special gift
for mathematics. He went on from there to complete his studies in Paris at
the Coll`ege Montagu. His aim was to join either the artillery or the engineers,
the branches of the army supposedly open to all classes of society,
but when he applied he was turned down. Although he could have been
rejected on medical grounds, the reason given by the minister was that only
candidates of noble birth were acceptable.
After this setback Fourier embarked on a career in the church. He
became a novice at the famous Benedictine Abbey of St Benoˆıt-sur-Loir,
where he was called on to teach elementary mathematics to other novices.
After taking monastic vows he became known as Abb´e (Father or Reverend)
Fourier, but instead of pursuing a career in the church he returned to Auxerre
to teach at the Ecole Militaire. By this time he was twenty-one and had
already read a research paper at a meeting of the Paris Academy.
During the first tempestuous years of the Revolution, Fourier was
prominent in local affairs. His courageous defence of victims of the Terror
led to his arrest by order of the notorious Committee for Public Safety
in 1794. A personal appeal to Robespierre was unsuccessful, but he was
released after Robespierre himself had been guillotined. Fourier then went
as a student to the short-lived Ecole Normale Sup` erieure. The innovative
teaching methods which had been introduced there made a strong impression
on him and it gave him the opportunity to meet some of the foremost
scientists of the day, including Lagrange, Laplace and Monge. The next year,
when the Ecole Polytechnique opened its doors, under its original name of
the Ecole Centrale des Travaux Publiques, Fourier was appointed assistant
lecturer to back up the teaching of Lagrange and Monge. However, before
long he fell victim to the forces of reaction and was arrested again. He had
an anxious time in prison but his colleagues at the Ecole successfully sought
his release.
In 1798 Fourier was selected to join an expedition to an undisclosed
destination. This proved to be Napoleon’s Egyptian adventure. Once the
military objectives had been secured, Berthollet and Monge established an
Egyptian Institute in Cairo, of which Fourier was made permanent secretary,
and the cultural arm of the expedition set to work studying the antiquities,
some of which were appropriated. On top of this activity Fourier was also
entrusted with some negotiations of a diplomatic nature and he even found
time to think about mathematics. He proposed that a report on the work
Jean-Baptiste Fourier (1768–1830) 87
of the Egyptian Institute be published and, on his return to France, was
consulted regarding its organization and deputed to write a historical preface
describing the rediscovery of the wonders of the ancient civilization.
When the Description de l’Egypte was published, Fourier’s elegant preface,
somewhat edited by Napoleon, appeared at the front of it.
Meanwhile Fourier had resumed his work at the Ecole Polytechnique.
Before long Napoleon, who had been impressed by his capacity for administration,
decided to appoint him prefect of the D´epartement of Is ` ere, based
at Grenoble and extending to what was then the Italian border. The office of
prefect was a demanding one, but it was during this period that Fourier wrote
his classic monograph on diffusion of heat entitled Th´eorie analytique de
la chaleur (On the Propagation of Heat in Solid Bodies) and presented it to
the Paris Academy in 1807. It was refereed by Lagrange, Laplace, Lacroix
and Monge. Lagrange was adamant in his rejection of several of its features
(especially the central concept of trigonometric or, as we say, Fourier series),
so its publication in full was blocked; only an inadequate five-page summary,
written by Laplace’s prot´eg´e Poisson, appeared. Later Fourier received
a prize from the academy for the work, but it was not until 1822 that his
theory of diffusion of heat was published. To quote from the preface to the
Th´eorie analytique de la chaleur, this ‘great mathematical poem’ as Clerk
Maxwell described it:
First causes are not known to us, but they are subjected to simple and
constant laws that can be studied by observation and whose study is
the goal of Natural Philosophy . . . Heat penetrates, as does gravity, all
the substances of the universe; its rays occupy all regions of space. The
aim of our work is to expose the mathematical laws that this element
follows . . . But whatever the extent of the mechanical theories, they
do not apply at all to the effects of heat. They constitute a special
order of phenomena that cannot be explained by principles of
movement and of equilibrium . . . The differential equations for the
propagation of heat express the most general conditions and reduce
physical questions to problems in pure Analysis that is properly the
object of the theory.
As prefect, Fourier’s administrative achievements included securing
the agreement of thirty-seven different communities to the drainage of a
huge area of marshland to make valuable agricultural land and the planning
of a spectacular highway between Grenoble and Turin, of which only the
88 From Rumford to Oersted
French section was built. Napoleon conferred on him the title of baron, in
recognition of his excellent work as prefect.
Fourier was still at Grenoble in 1814 when Napoleon fell from power.
The city happened to be directly on the route of the party escorting the
Emperor from Paris to the south and thence to Elba; to avoid an embarrassing
encounter with his former chief, Fourier negotiated a detour in the route. No
such detour was possible when Napoleon returned on his march to Paris in
1815, so Fourier compromised, fulfilling his duties as prefect by ordering the
preparation of the defences – which he knew to be futile – and then leaving
the town by one gate as Napoleon entered by another. His handling of this
awkward situation did not adversely affect their relationship. In fact the
Emperor promptly gave him the title of count and appointed him prefect
of the neighbouring De´partement of the Rhoˆ ne, based at Lyon. However,
before the end of the Hundred Days Fourier had resigned his new title and
appointment in protest against the severities of the regime and returned to
Paris to concentrate on scientific work.
This was the low point in Fourier’s life. For a short while he was
without employment, subsisting on a small pension, and out of favour politically.
However, a former student at the Ecole Polytechnique and companion
in Egypt was now prefect of the D´epartement of the Seine. He appointed
Fourier director of the Statistical Bureau of the Seine, a post without arduous
duties but with a stipend sufficient for his needs.
Fourier’s last burst of creative activity came in 1817/8 when he
achieved an effective insight into the relation between integral-transform
solutions to differential equations and the operational calculus. There was
at that time a three-cornered race in progress among Fourier, Poisson and
Cauchy to develop such techniques. In a crushing response to a criticism by
Poisson, Fourier exhibited integral-transformsolutions of several equations
that had long defied analysis, and paved the way for Cauchy to develop a
systematic theory, en route to the calculus of residues.
In 1816 Fourier was elected to the reconstituted Acad´emie des Sciences,
but Louis XVIII could not forgive his acceptance of the Rhoˆ ne prefecture
from Napoleon and at first refused to approve the election. Diplomatic
negotiation eventually resolved the situation and his renomination the next
year was approved. He also had some trouble with the second edition of the
Description de l’Egypte (for now the references to Napoleon needed revision),
but in general his reputation was recovering rapidly. He was left in
a position of strength after the decline of the Soci´et´e d’Arcueil and gained
the support of Laplace against the enmity of Poisson. In 1822 he was elected
Jean-Baptiste Fourier (1768–1830) 89
permanent secretary of the Acad´emie des Sciences. In 1827, like d’Alembert
and Laplace before him, he was elected to the literary Acad´emie Franc¸ aise;
and he also succeeded Laplace as president of the council of the Ecole Polytechnique.
Outside France he was elected to the Royal Society of London.
Fourier’s health was never robust and, towards the end of his life, he
began to display peculiar symptoms that are thought to have been due to
a disease of the thyroid gland called myxoedema, which he had possibly
contracted in Egypt. As well as causing certain physical symptoms, this
disorder can lead to a dulling of the memory, which may account for the
mishandling of some of the memoirs he received as permanent secretary and
for the rambling character of those he wrote himself towards the end of his
life. Early in May 1830 he suffered a collapse and his condition deteriorated
until he died on May 16, at the age of sixty-two. The funeral service took
place at the church of St Jacques de Haut Pas, and he was buried in the
cemetery of P`ere Lachaise, close to the grave of Monge.
Throughout his career, Fourier won the loyalty of younger friends
by his unselfish support and encouragement; in his later years he helped
many mathematicians and scientists, including Abel, Dirichlet, Oersted and
Sturm. His scientific achievements lie mainly in the study of the diffusion
of heat and in the mathematical techniques he introduced to further that
study. His interest in the problem may have begun while he was in Egypt,
but the main work on it was done at Grenoble. Profound study of nature, he
used to say, is the most fertile source of mathematical discoveries, but the
mathematical discoveries he made have found a wide variety of applications,
as well as playing a highly important role in mathematical theory.
Fourier’s viewpoint was that of rational mechanics. He had a superb
mastery of analytical technique and this power, guided by physical intuition,
brought him success. Previously the equations used in the leading problems
of rational mechanics had usually been non-linear and they were solved by
ad hoc methods. Fourier created a coherent method by which the various
components of an equation and its solution in series were neatly identified
with the various aspects of the physical solution being analysed. He also
had a uniquely sure instinct for interpreting the asymptotic properties of
the solutions of his equations for their physical meaning. So powerful was
his approach that a full century passed before non-linear equations regained
prominence in rational mechanics.
In mathematical physics Fourier’s ideas have proved to be much more
fruitful than those of Laplace. He also had a long-standing interest in the
theory of equations and was trying to complete a book on the subject towards
90 From Rumford to Oersted
the end of his life. Some of his ideas on the subject evolved into Sturm’s
theorem, whereas others have recently found applications in the theory of
linear programming. He was also interested in dynamics and in the theory of
probability. As a mathematician, Fourier had as much concern for practical
problems of rigour as anyone in his day except Cauchy and Abel, but he could
not conceive of the theory of limiting processes as a meaningful exercise in
its own right. Poisson and Biot, outclassed as rivals in the theory of diffusion
of heat, tried for years to belittle Fourier’s achievements.
The later history of thermodynamics is complex. After Fourier, the
next important advances in understanding the nature of heat were due to
the theoretician Sadi Carnot, set out in his great memoir of 1824 Reflexions
sur la puissance motrice du feu (Reflections on the Motive Power of Fire).
Although Fourier, with other academicians, heard him lecture on his theories,
he did not seem to have appreciated their importance; after Carnot
died at the age of thirty-six they were neglected for years.
Thomas Young (1773–1829)
We now return to England. Quakers, members of the Religious Society of
Friends, were widely respected for their integrity as men of business; they
adopted a distinctive mode of dress, refused to take oaths and contributed
many distinguished men to science in eighteenth-century England. Thomas
Young, mentioned earlier, was one of them. His limited influence on science
was the result of his personality, his poor choice of methods of communication
and his frequent changes of occupation. He published sporadically,
often in obscure and inappropriate ways; his prose was awkward and his
Thomas Young (1773–1829) 91
mathematics inadequate. He was a gentleman scientist with many good,
even brilliant, ideas who lived to see others receive the credit and fame for
completing what he had begun. He made acute suggestions, but left them
for others to develop. The German scientist Helmholtz, whose work was
considerably influenced by Young’s ideas, gave his opinion that
he was one of the most clear-sighted men who have ever lived, but he
had the misfortune to be too greatly superior in sagacity to his
contemporaries. They gazed at him with astonishment, but could not
always follow the bold flights of his intellect, and thus a multitude of
his most important ideas lay buried and forgotten in the great tomes of
the Royal Society of London, till a later generation in tardy advance
made his discoveries and convinced itself of the accuracy and force of
his inferences.
Thomas Young was born in the village of Milverton, near Taunton,
Somerset, on June 13, 1773. His father, of the same name, was a cloth
merchant, banker and landowner. He and his wife Sarah (n´ee Davis) were
Quakers. Thomas was their eldest son, in a family that grew to nine.
Perhaps because of the size of the family, he was sent to live until the age of
seven with his maternal grandfather, Robert Davis of Minehead, who was
an enthusiastic classicist.
Thomas was a precocious child, with a phenomenal memory, especially
for languages. He could read by the age of two. The first school he
went to, a boarding school in Bristol, had nothing to teach him. After a year
back in Milverton, where he read science books borrowed from a neighbour,
he went to a school at Compton, Dorset, where he not only studied classics,
mathematics and natural philosophy but was also taught practical skills.
Young very early showed real mathematical ability. Prodigies tend to excel
in languages, mathematics or music.
After leaving school, at the age of 13, he returned to Milverton and
studied various Near-Eastern languages, including Syriac (western Aramaic)
and Hebrew. He also began making optical instruments and is said before
long to have mastered Newton’s Opticks and Principia. In 1787, aged only
fourteen, he went to join the grandson of the Quaker banker David Barclay.
The boy, named Hudson Gurney, was being educated privately, and it was
thought that he should have a companion in his studies, but to some extent
Thomas Young also acted as tutor to the younger boy. The two became
life-long friends; later Hudson Gurney became well known as an antiquary,
writer and politician.
92 From Rumford to Oersted
Although Barclay usually spent most of the year at his country house
near Ware in Hertfordshire, he generally resided for four of the winter
months in London. So during the five years Thomas Young spent in the
Barclay household, he was partly in London, where there were lectures he
could attend and libraries he could use. It was during one of the London
visits that he came to the notice of his great-uncle Richard Brocklesby,
who was prominent in the medical world. A fellow of the College of Physicians
and of the Royal Society, he had written on the therapeutic value of
music and had produced a standard treatise on military hygiene. Brocklesby
was immensely impressed by the accomplishments of his brilliant young
relative.
In 1789, in the middle of his time with the Barclays, Young was taken
ill with suspected consumption. Brocklesby succeeded in restoring him to
health and advised him to take more care of himself. At Brocklesby’s London
residence Young met most of the distinguished literary men of the day and
impressed them with his classical scholarship. On the advice of his greatuncle,
he took up medicine with a view to succeeding to his practice once he
qualified. In 1793 he entered St Bartholomew’s Hospital and in the following
year was elected to the Royal Society for an original paper on the action of the
ciliary muscles in the accommodation of the eye. The Duke of Richmond,
a man of the world, wrote to Brocklesby, who was his medical adviser:
But I must tell you how much pleased we all are with Mr Young.
I really never saw a young man more pleasing and engaging. He seems
to have already acquired much knowledge in most branches, and to be
studious of obtaining more: it comes out without affectation on all
subjects he talks upon. He is very cheerful and easy without assuming
anything; and even on the peculiarity of his dress and Quakerism he
talked so reasonably, that one cannot wish him to alter himself in any
one particular.
The duke, who was Master-General of the Ordnance at the time, offered to
appoint the young man as his private secretary, but, as Young wrote to his
mother,
I have very lately refused the pressing offer of a situation which would
have been the most favourable and flattering introduction to political
life that a young man in my circumstances could desire. I might have
lived at a duke’s table, with a salary of £200 a year as his secretary, and
with hopes of a more lucrative appointment in a short time. I should
Thomas Young (1773–1829) 93
have been in an agreeable family, have had enough time to study, a
library, a laboratory and philosophical apparatus at my service; and I
was not ashamed to allege my regard for our Society as a principal
reason for not accepting the proposal.
As Quakers are pacifists, it might have been the military connection which
inspired his refusal.
Although body-snatching had reached scandalous proportions,
Edinburgh at this time was the most highly regarded place in Europe for a
medical education. Young spent the next year in the Scottish capital, studying
modern languages as well as medicine. While he was there he ceased
to display the outward characteristics of Quakerism, mixed in society and
learnt to play the flute, to sing and to dance. Having decided to spend the
next academic year in Go¨ ttingen he ended his stay in Scotland with an
ambitious tour of the Highlands, still something of an adventure.
The University ofGo¨ ttingen, known as the Georgia Augusta, had been
founded in 1727 on the model of Oxford and Cambridge by King George II
of Great Britain, who was also Elector of Hanover. The new foundation
attracted students from all over Germany and from elsewhere in Europe as
well. Although its endowments were more generous and it enjoyed greater
autonomy, it was still in many respects a typical German university of that
period. According to the writer Heinrich Heine, ‘Go¨ ttingen is renowned for
its university and its sausages; the inhabitants are divided into four classes:
students, professors, Philistines and cattle.’
In G¨ ottingen Young took full advantage of the excellent library and
other facilities. He was struck by the way that professors might entertain
students in their homes and yet completely ignore them if they passed them
in the street. He commented that ‘science here has one advantage that the
doctrines of both countries are well known here, while the English attend
very little to any opinion but those of their own country’. In addition to
medical studies he learnt horsemanship and devoted considerable attention
to music and other arts. At the end of the year he left with the degree of
doctor of physic, surgery and midwifery from the Georgia Augusta, having
submitted a thesis De corporis humani viribus conservatricibus. He travelled,
mainly on foot, to Dresden, where he spent a month studying the art
collections, and then returned to London, via Berlin and Hamburg, a remarkably
accomplished and educated young man. ‘His language was correct and
his utterance rapid.’ He was ‘emphatically a man of truth’ and ‘could not
bear the slightest degree of exaggeration’; he was ‘accustomed to reciprocate
94 From Rumford to Oersted
visits with the best society’ and was ‘always ready to take part in a dance
or a glee, or to join in any scheme of amusement calculated to give life or
interest to a party’.
In 1797, on Brocklesby’s recommendation, Young entered Emmanuel
College, Cambridge, where he spent two years as a fellow-commoner, which
gave him the right to dine with the fellows rather than with the other undergraduates.
He had been caught by a change in the regulations of the College
of Physicians; previously two years of university study had been required of
a medical practitioner, now it had to be two years at the same university.
The alternative was to return to Edinburgh for a second year, which would
have been far better professionally and avoid the problem of the religious
test which involved taking an oath. As a Quaker, in the first case of its kind,
he was given leave not to take the oath. Being technically a student, Young
found that the more distinguished senior members of the university were
just as aloof as they had been atGo¨ ttingen, but he made some friends among
the junior members, among whom he was known as ‘Phenomenon Young’.
He was seldom seen in the libraries, being mainly occupied with experimental
work on sound and light, including the phenomenon of interference, the
results of which he communicated to the Royal Society. He described what
he was doing in a letter to one of his scientific friends:
I amashamed to find how much the foreign mathematicians for these
forty years have surpassed the English in the higher branches of these
sciences. Euler, Bernoulli and d’Alembert have given solutions to
problems which have scarcely occurred to us in this country. I have
had particular occasion to observe this in considering the figure of
vibrating chords, the sound of musical pipes and some similar matters
in which I fancied I had hit on some ideas entirely new, but I was glad
to find them in part anticipated by Daniel Bernoulli in 1753 and 1762.
There are still several particulars respecting the gyration of chords and
formation of synchronous harmonics, the combination of sounds in
the air, the phaenomenon of beats, on which I flatter myself that I
shall be able to throw some new light.
Already he was beginning to follow Hooke and Huygens in regarding light
as a wave motion, like sound.
Not long after he had gone up to Cambridge his great-uncle died,
leavingYoung a fortune of £10 000, a large London house, a library and works
of art. In preparation for taking over his benefactor’s medical practice, Young
gained some further experience in the London hospitals and then established
Thomas Young (1773–1829) 95
himself in practice inWelbeck Street. While he continued his contributions
to literary scholarship and science, he often published anonymously to avoid
any suspicion that he might be neglecting his patients.
In 1800 Young, as we know, was appointed professor of natural philosophy
at the Royal Institution; he was also editor of its publications and
superintendent of its premises. As a lecturer to a popular audience he was
not a success; he displayed extraordinary erudition but his style was too
didactic and condensed. Friends advised him that his professorial responsibilities
were interfering too much with his medical work and so he resigned
his chair after only two years, to devote himself largely to medicine. In 1802
he was appointed secretary of the Royal Society, became foreign secretary
two years later and held that office for the rest of his life. In 1804, at the age
of thirty, he married an ‘extremely young’ lady named Eliza Maxwell, who
had Scottish aristocratic connections.
Young was awarded the degree of M.B. at Cambridge in 1803 and that
of M.D. five years later. He was elected fellow of the College of Physicians
in 1809, became censor in 1813 and 1823 and was Croonian Lecturer in
1822 and 1823. During the winters of 1809 and 1810 he gave courses of
lectures at the Middlesex Hospital, but these again were not a success with
the students. In 1811 he was appointed physician at the highly respected
St George’s Hospital, a position he held until his death. Yet as a medical
practitioner success eluded him and in 1814 he retired from practice. This
was not only an exciting time for medical research but also a period when
medical practice was being modernized. Perhaps Young was ahead of his
time.
Major changes of occupation were a feature of Young’s later life. He
published several papers dealing with life insurance and was appointed
inspector of calculations and physician to the Palladium Insurance Company.
He became secretary of the Commission on Weights and Measures
and of the Board of Longitude. In 1818 he was appointed superintendent of
the Nautical Almanac; his view that the almanac should, as in the past, supply
only information of importance in navigation brought him into conflict
with many astronomers of the day, who wished it to cater for their needs as
well. To a large extent these various activities were related to his position
as foreign secretary of the Royal Society, but he also returned to his early
interest in philology.
All knowledge of the meaning of the hieroglyphic inscriptions found
on Egyptian remains had been lost for 1300 years. Many unsuccessful
attempts to interpret them had been made during the eighteenth century,
96 From Rumford to Oersted
but it was thought that at least some of the characters represented sounds
and that those enclosed in an oval line represented proper names. When,
in 1790, a tablet, somewhat damaged, was discovered at Rosetta, at the
mouth of the Nile, with a decree of the priests inscribed on it in hieroglyphic
(sacred), enchorial (cursive) and Greek characters, it was realized that the
Greek text might provide a clue to the interpretation of the Egyptian inscriptions.
The tablet was placed on display in the British Museum. Impressions
of the inscription were circulated to scholars all over Europe, but
twenty years went by without much progress in solving the problem of interpretation.
Meanwhile more hieroglyphic inscriptions had been discovered
following Napoleon’s expedition to Egypt.
In 1813 Young started attempting to decipher the inscriptions on the
Rosetta stone and by the following year he had translated the ‘enchorial’, or
domestic, running script and had concluded that the enchorial was derived
from the hieroglyphic. Pressure of other work prevented him from doing
much more for some time, but he returned to the problem in the closing
years of his life and made remarkable progress. The illustrious Champollion
was a specialist in a field where Young was a gifted amateur, but at
least he set Champollion on the right track. Young was still working on an
Enchorial Egyptian Dictionary up to the end of his life; it was published
in 1830, shortly after his death. This was the most notable of a number of
works of scholarship dating from his last decade. Another that should be
mentioned is his work as a major contributor to the fourth edition of the
Encyclopaedia Britannica, published in 1819. His lengthy article ‘Egypt’
became famous; he also contributed a large number of the biographical
notices.
In the latter part of his life Young usually spent the period from
November to June each year in London and the rest of the year in the fashionable
south-coast resort of Worthing, where he tried unsuccessfully to
build up a medical practice. After 1815, when peace had been restored on
the continent, he made several visits to Paris. The first was in 1817, when
he met Arago, Laplace and Baron von Humboldt amongst others. Four years
later he returned to the continent for a more extended tour, including Italy.
In 1827 he received international recognition when, in succession to Volta,
he was elected to the select band of eight foreign associates of the Paris
Academy. The following year when he was in Paris again it was noticed
that his strength was declining. In London he moved from Welbeck Street
to a house in Park Square, not far away, and it was there that he died of heart
disease on May 10, 1829, at the age of fifty-six. He was buried in the vault of
Andr´e-Marie Amp`ere (1775–1836) 97
the family of his wife Eliza at Farnborough. A profile medallion was placed
in Westminster Abbey with an inscription referring to his achievements.
In his essay On the Cohesion of Fluids Young gave in nonmathematical
language the theory of capillary action soon after brought
forwards by Laplace independently. He was also the first to use the term
‘energy’ for the product of the mass of a body and the square of its velocity.
In the theory of elasticity he introduced the formula relating stress to strain
which we know as Young’s modulus, but characteristically his definition
is hopelessly obscure. His theory of tides explained more tidal phenomena
than had any previous one. Apart from his contributions to the theory of
light and sound, he wrote many important papers on medical subjects.
Young has been called the founder of physiological optics, building
on foundations laid by Kepler, Descartes, Huygens and others. He was the
first to prove conclusively that the accommodation of the eye for vision at
different distances was due to a change in curvature of the crystalline lens.
His memoir on the mechanism of the eye contained the first description and
measurement of astigmatism, a condition from which he suffered himself.
He also gave an explanation of colour blindness. When Young began to write
on physical optics the wave theory of light had made little headway against
its rival the corpuscular theory, which was favoured by Newton. Young
developed the wave theory, the vibrations being transverse to the ray, and
obtained many experimental results supporting that view, but his work
was little understood in his lifetime. Not long afterwards Fourier’s disciple
Augustin Fresnel contributed his mathematically sophisticated wave theory
of light, which went far beyond Young’s ideas.
Andr´e-Marie Amp`ere (1775–1836)
It is perhaps unfortunate that, because of the dates of birth, the profile of
the French physicist Andr´e-Marie Amp`ere must precede that of the Danish
physicist Hans Oersted, because it was Amp`ere who gave the first mathematical
treatment of electromagnetism, the marvellous discovery of
Oersted. The son Andr´e-Marie of Jean-Jacques Amp`ere and Jeanne-
Antoinette (n´ee Desuti`eres-Sarcey) was born about January 20, 1775 in Lyon,
the second city of France, where both sides of the family were dealers in
silks. Just before marriage Jean-Jacques had acquired a country estate at
Poleymieux-les-Monts-d’Or, a small village in the picturesque hills a short
distance up the river Sa ˆ one: this was used initially as a summer retreat
from the city and later as the family’s permanent home after he retired from
business in 1782. Thus, for the first seven years of his life, their son and his
98 From Rumford to Oersted
elder sister Antoinette were able to enjoy both the busy life of the city and
the peace of the country. Three years after this he acquired a younger sister
Josephine, of whom more later.
The interests of Jean-Jacques included Latin and French literature,
as well as several branches of science, and, being a follower of the social
philosopher Rousseau, he encouraged his son to educate himself by reading
the books in his extensive library (although an education on the lines laid
down in Emile might be all very well, according to Arago the discipline
of a public school might have had a most salutary influence on Amp` ere’s
character). The boy, who displayed unusual powers of concentration and
a prodigious memory, read his way through Diderot’s great encyclopaedia.
Having been forbidden the rigours of geometry because of his tender years,
he defied parental authority and worked out the material in the early books
of Euclid by himself. When he found that the classics of science tended to
be in Latin, he taught himself the language in order to be able to study the
works of Euler and his contemporaries. He read the M´ecanique analytique
of Lagrange and worked through all the calculations it contains.
Later he described the three most influential events in his life as his
first communion, which established him in the faith of his fathers, the
Eulogy of Descartes, which instilled in him a belief in the nobility of a life
in science, and the fall of the Bastille, which decided his political sentiments
Andr´e-Marie Amp`ere (1775–1836) 99
for his entire life. The first two years of the Revolution, ending in the
attempted flight of the royal family, had some impact, even in Poleymieux,
but at first Lyon was spared the excesses which culminated in the Terror.
The city, a royalist stronghold, was in the hands of the relatively moderate
Girondins. Jean-Jacques Amp`ere took on the responsibilities of magistrate
and presiding legal functionary of the police tribunal, but this led him into
trouble when the Jacobin government in Paris, supported by sympathisers
in Lyon itself, took control of the city by force. Jean-Jacques was arrested
and imprisoned, tried for having approved a warrant of arrest for one of the
leading Jacobins, found guilty and promptly guillotined.
This devastating experience left Amp`ere averse to violence and militarism.
His mother, a deeply religious person, now took charge of his education.
Fortunately the family property had been transferred into her name, so
that at least some of it was shielded from confiscation. A lengthy period of
depression, during which he occupied himself mainly with botanical studies,
was broken by a love affair with the daughter Cath´erine-Antoinette Julie
Carron of a local family in somewhat similar circumstances to his own.
After he had courted her assiduously for three years, they were married
in August 1799; their first and only child Jean-Jacques was born the next
year.
Already Amp`ere had begun publishing his first memoirs in mathematics
and these brought him to the notice of the highly centralized French
scientific community. At the same time he made some close and enduring
friendships among the intelligentsia of Lyon. He also undertook some private
tutoring of mathematics students and some teaching at local schools.
In 1802 he left the city to become professor of physics and chemistry at the
Ecole Centrale du D´epartement de l’Ain at Bourg-en-Bresse, which was to
be the scene of much of his early scientific work. Before the Revolution it
had been staffed by Jesuits, but, after a transitional stage, it was secularized
and renamed the Lyc´ee Lalande. The plan was for him to gain some teaching
experience before returning to Lyon to work in a new Lyc´ee that was being
established by Napoleon. Meanwhile he was living in Bourg while his wife
Julie was forty miles away in Lyon. In 1803 she died of what may have been
a malignancy, leaving their three-year-old son in his care.
Following this second major tragedy in his life, Amp`ere was appointed
to a post at the new Lyc´ee in Lyon, but after less than a year he decided
to move to the capital to make more of a name for himself in the world of
science. He was appointed r ´ep´ etiteur for analysis at the Ecole Polytechnique.
This meant that he was essentially a tutor to the students who were lectured
100 From Rumford to Oersted
to by the professor of analysis, initially Augustin Cauchy. By 1809 he had
been promoted to professor of analytical mathematics and mechanics and
had become a member of the Legion of Honour. All too soon he became
involved in the quarrels of the scientific community in the French capital
and came to regret leaving Lyon.
The period between 1804, whenAmp`ere arrived in Paris, and his death
in 1836 was a time of complex political and social change. He witnessed
the consequences of Napoleon’s coronation as emperor, his military successes
and subsequent defeat, the initial restoration of Louis XVIII in 1814,
Napoleon’s return for the Hundred Days, the second restoration of 1815 and
the revolution of 1830. No supporter of Napoleon, Amp`ere favoured the idea
of a paternal and enlightened sovereign as head of state.
As well as his chair at the Ecole Polytechnique, Amp` ere, as was normal,
collected a number of other posts. Notably, in 1808 he was appointed
inspector-general of the newly formed university system, a post that he held
almost continuously for the rest of his life. In 1814 he was elected to the
Paris Academy and ten years later he was appointed professor of physics
at the Coll`ege de France. This was a most fruitful period for his scientific
work, especially after 1820 when, inspired by Oersted’s discovery of electromagnetism,
he made most of the discoveries for which his name is so
renowned and collected them together in his great 1827 M´emoire sur la
th´eorie math´ematique des phenom`enes ´electrodynamiques, uniquement
d´eduite de l’exp ´erience (Memoir on the Mathematical Theory of Electrodynamic
Phenomena, Uniquely Deduced from Experiments). In this work,
which has been described as the Principia of electrodynamics, he introduced
the important distinctions between electrostatics and electric currents
and between current and voltage, demonstrating that current-carrying
wires exert a force on each other, and gave an explanation of magnetism in
terms of electric currents.
Unfortunately there was to be further misery in Amp` ere’s private life,
to some extent self-imposed. Another Lyonnais living in the capital, Jean-
Baptiste Potot, had a 26-year-old daughter Jeanne-Franc¸ oise, who went by
the name of Jenny. The surviving descriptions of her family are uniformly
disparaging: ‘it was a household as bourgeois as possible, in the pejorative
sense in which artists understand that word: narrow ideas, prejudices,
pretensions, living only for money and vanity, not having the least idea
of the sciences, exactly the opposite of what it should have been for a big
child as simple and modest as Amp` ere’. He courted Jenny with the same
passion that had animated his relationship with Julie. As soon as they were
Andr´e-Marie Amp`ere (1775–1836) 101
married and had started living together she began to distance herself from
him. Her interest in the marriage seemed to be mainly financial: after the
birth of a daughter, Josephine-Albine, Amp`ere was granted a separation and
obtained custody of the child. To take care of his household, he persuaded
his mother and his sister Josephine to come to Paris, bringing his son Jean-
Jacques with them. Amp` ere’s friends in Lyon considered that he was being
selfish, and in fact his mother did not survive the move for more than eighteen
months. Meanwhile Amp`ere was having another love affair, but the
object of his attentions married someone else. In addition to all this, his
relations with his seven-year-old son by his first wife became strained.
Amp`ere found some solace in his mathematical work, writing to a
friend ‘I am going to take up mathematics again. I have some trouble at first,
but when I have overcome the initial repugnance, I no longer want to leave
the calculations. I still experience a great charm there when I can eliminate
every other thought and occupy myself with it alone, absolutely alone.’ He
completed a significant memoir on partial differential equations, presented
it to the Academy, made the customary social calls and, when the vote on
membership was taken in November 1814, was successful, beating Cauchy.
Ironically Cauchy was just at the beginning of his most creative period
whereas Amp`ere hardly touched mathematics afterwards, concentrating on
natural science instead. Unfortunately Amp`ere lacked perseverance; he was
always flying off to something new.
The middle-aged Amp`ere returned to the religious practices of his
youth. He sold off the family property at Poleymieux and bought a house in
Paris, where he took scholarly boarders who constituted a ready audience
when he needed someone to talk to, as he often did. He began taking more
interest in the education and ambitions of his son; the boy was quite bright,
learning to read at an early age, but in childhood was subject to violent
tantrums. By this time he was well-trained in languages, literature and the
sciences. Initially Amp`ere encouraged him to make a career in the chemical
industry, but Jean-Jacques was more interested in becoming a writer.
In the last ten years of his life Amp`ere gradually lost interest in science;
for example, he did not keep up with Faraday’s discoveries. Financial
problems became a daily concern. His sister ran up large debts maintaining
his household, while his son used the inheritance from his grandmother
to enjoy leisurely journeys abroad. Both father and son were temperamental,
given to bursts of anger interspersed with long periods of silence; it was
impossible for them to live under the same roof. In 1820 Jean-Jacques met the
celebrated Madame de R´ecamier and fell under her spell. This stimulated
102 From Rumford to Oersted
him to complete his first play, Rosamunde, which his father tried to get
produced. Madame de R´ecamier went off to Italy for a year, pursued by
Jean-Jacques. On his return to Paris he lost his interest in writing historical
dramas but gradually found a new one in literary history. He embarked on
an academic career, with such success that by 1833 he was teaching foreign
literature at the Coll`ege de France. He never married but maintained a
strained and unsatisfying relationship with Madame de R´ecamier until her
death in 1850.
Meanwhile Amp` ere’s daughter Albine became a source of concern.
She had married a military man with a prediliction for strong drink, violence
and gambling. He also had a dangerous habit of trying to avoid payment of
his gambling debts. After a tempestuous period in Paris he was sent off to
Louisiana, where two of his brothers had settled. Amp`ere himself displayed
remarkable patience and sympathy while all this was happening. After his
death Albine’s husband returned to Paris quite unreformed and before long
he was institutionalized. Albine herself became increasingly deranged. She
died in 1842; her father did not live to witness the final years of her unhappy
life.
Amp`ere was one of those who could obtain no inspiration when
seated; he preferred to stand up or walk around when thinking. Later in life
his behaviour became distinctly odd; his pupils made fun of him. His study
was open to all, but visitors found it difficult to leave it without playing a
game of chess with him. The serious financial problems he experienced in
later years were due partly to his expenditure on scientific instruments. His
scientific work came under criticism; among the academicians only Fourier
received his theories favourably. Outside France criticism was even more
severe. After 1829 Amp` ere’s years of scientific creativity had come to an
end and his health began to deteriorate. Suffering from bronchitis, laryngitis,
rheumatism and occasionally pneumonia, he wintered in the south
of France, with his son for company. He was in Marseille when he died
from pneumonia on June 10, 1836. Amp` ere’s remains were transferred to
the cemetery in Montmartre in 1869. The house at Poleymieux is now a
national museum, dedicated to his life and work.
Hans Christian Oersted (1777–1851)
At the opening of the nineteenth century very little was yet known
about electricity and magnetism. Hans Christian Oersted, who discovered,
almost by chance, the fundamental relation between them, was born in
the small Danish town of Rudjøbing on August 14, 1777. His father Søren
Hans Christian Oersted (1777–1851) 103
Christian Oersted was an impecunious pharmacist. His mother Karen (n ´ee
Hermansen) gave birth to another son, Anders Sandoe, the next year and
other children later. No formal schooling was available in Rudjøbing, which
is on the Baltic island of Langeland, but the resourceful pharmacist overcame
this problem. The two boys, while they were still young, were placed
with a German wigmaker, Christian Oldenberg, and his Danish wife. Their
father arranged for Oldenburg to teach them the German language and his
wife to help them learn to read and write. As for arithmetic, Oldenburg’s
knowledge was limited to addition and subtraction, but happily a local
youth imparted the arts of multiplication and division. From the mayor of
Rudjøbing they learnt a smattering of French, from the baker a little drawing
and from the local surveyor some geometry. Moreover, when Hans was
twelve years old he assisted his father in the pharmacy and thus acquired a
useful grounding in chemistry.
Various difficulties notwithstanding, Hans and Anders studied hard;
their intelligence was above average, and their parents used every available
means to encourage them. The two boys were so successful that they passed
with honours the entrance examination for the University of Copenhagen,
the only one in the country. There they received a little financial support
from the state and made up the remainder by teaching. They were both
interested in science, but the ambition of Anders was to become a lawyer,
104 From Rumford to Oersted
whereas Hans was more inclined towards literature and philosophy, subjects
in which he won prizes for his work. For his doctoral thesis he wrote about
the architectonics of natural metaphysics, for he was a passionate disciple
of Kant. It must be remembered that in much of Europe a doctorate is a first
degree.
The year 1800, memorable for Volta’s invention of the battery as a
source of electric current, saw Oersted again working in a pharmacy, this
time in Copenhagen, while the owner was away on a European tour. The
young man, aware of the discoveries which had just been made by Volta,
welcomed the opportunity this gave him for scientific research. On the
return of the owner of the pharmacy, who was professor of surgery at the
university, Oersted organized a scientific tour for himself, with the help of
a travel grant from the government. In Germany he found an abundance
of theory, but it was experimental work that interested him more. In Paris
he rashly gave a lecture, which was greeted by ridicule; it taught him to be
more careful in future. On the return leg of the tour he visited Brussels,
Leiden, Haarlem and Amsterdam. When he returned to Copenhagen he
found that the university building had been damaged by fire, and the physical
laboratory destroyed. While waiting for a suitable opening he gave some
public lectures, which showed that he had a gift for teaching. Within two
years Oersted was assistant professor of physics at the university and also
held a position at the military school. Three years later he produced a textbook
of mechanical physics and published in French an account of some
research he had undertaken on the identity of electric and chemical forces.
In 1812–13 Oersted made another tour of France and Germany. This
time he settled in Berlin for a while and published there in German the
research paper which already had appeared in French. The next year, when
he was back in Copenhagen, he married Inger Birgitte Ballum, whose father
was pastor of Kjelby, on the small island of Moer. At about the time of his
marriage, he associated himself with a movement to introduce the German
language into chemical terminology in place of French and Greek. In addition
he sought to raise science at the university to the status enjoyed by
theology.
Oersted usually devoted five hours a day to teaching and it was his
custom each month to present an account of new scientific advances in a
special lecture. It was at one of these that, in the year 1820, or thereabouts,
he made his historic discovery: that an electric current can displace a compass
needle. He assembled the apparatus, ready to try out after his lecture,
and asked the audience whether they would like to remain and see what
Hans Christian Oersted (1777–1851) 105
happened. At first the movement was so small, and its direction so unexpected,
that Oersted was unsure that it had been caused by the current. So
he tried again with a much stronger current and found that the deflection
was unmistakable. After the discovery had been announced he received honours
from all sides. The Royal Society of London, for example, awarded him
the Copley medal, while the Paris Academy elected him a corresponding
member.
Of all the congratulations he received from men of science, the most
emphatic were those of Thomas Young, who spoke of the marvellous discovery
that elevated Denmark to a rank in science it had not held since the
days of Tycho Brahe. In Germany it was said that Oersted’s experiments
in magnetism were the most interesting that had been carried out in that
domain of science for a thousand years. Faraday said of him that ‘his constancy
in the pursuit of his subject, both by reasoning and experiment, was
well rewarded in the winter of 1819 by the discovery of a fact that not a single
person beside himself [Oersted] had the slightest suspicion, but which, when
once known, instantly drew the attention of all who were able to appreciate
its importance and value’.
A third state-aided tour in 1822–3 took Oersted to England, where he
met Faraday, as well as to France and Germany. On his return he founded
the Danish Society for the Promotion of Scientific Knowledge, a major
vehicle for his efforts to raise the consciousness of progress in science among
the people of Denmark. In 1829 he became director of the Polytechnic
Institute in Copenhagen, a position he held for the rest of his life. He also
created a special laboratory for research on magnetism following a visit to
Go¨ ttingen, where he took advice from Carl Friedrich Gauss.
Towards the close of his life Oersted wrote to a friend that
in my family I am as happy as a man can be. I have a wife whom I love,
and children who are dear to me and who prosper. I have three sons –
of whom one is of age and is employed in the forestry service of the
king – and four daughters, of whom the eldest three are either married
or betrothed. My brother, who for some time was commissioner of the
king in our provincial parliament, has recently become a Minister of
State. As for me, I am still a professor and director of the polytechnic
school and secretary of the Royal Society of Sciences.
Oersted’s eldest daughter Karen married the professor of chemistry
at the university; another, Marie, married the pastor of a place in Zealand.
The youngest, Matilda, remained to cherish her father’s old friend Hans
106 From Rumford to Oersted
Christian Andersen, who bequeathed to her the manuscripts of his famous
stories. The husband of Oersted’s sister, Barbara Albertine, became president
of the Supreme Court of Norway. His brother Anders became prime minister
of Denmark. Another brother, Niels Randulph, an officer in the Russian
army, fell at the battle of Leipzig in 1813. They had come a long way from
the impecunious pharmacist of a generation or two before.
Oersted’s study of Danish literature was unceasing, and he published
a great deal of non-scientific work himself, usually related to his metaphysical
interests; he also wrote for the newspapers. In his later years he was
described as of open countenance, of florid complexion, somewhat stout, in
manners kindly, by nature gracious, loyal to the king, devoted to his country
and to the cause of humanity. In his scientific work he was often baffled but
never discouraged, his perseverance helped him to the end. The jubilee of
his association with the university in 1850 was celebrated by a torchlight
procession of his past and present students. The Danish government presented
him with a country house near Copenhagen, but he did not live to
enjoy it for long; within a few months he became ill and died peacefully in
the Danish capital on March 9, 1851.