Joseph Valentin Boussinesq


Quick Info

Born
13 March 1842
Saint-André de Sangonis, Hérault, France
Died
19 February 1929
Paris, France

Summary
Joseph Boussinesq was a French mathematician and physicist who made contributions to the theory of hydrodynamics, vibration, light, and heat.

Biography

Joseph Boussinesq was born in Saint-André de Sangonis which is a small town in the south of France, just over 30 km north east of Beziers and about the same distance west of Montpellier. His father, Jacques Boussinesq, was a farmer who owned a family farm in the district, while his mother, Anne-Marie Cavalier, was the daughter of an industrialist. Both parents wanted to see their son educated, which was certainly not compulsorily at this time, and he attended both primary and secondary education locally. However, much of his education was due to one of his uncles, a highly educated priest. From this uncle he learnt Latin and Greek as well as how to study on his own. After completing his secondary education, Boussinesq wanted to study at Montpellier, the closest town where he could undertake higher education, but he required financial support to enable him to study there.

The problem was that Boussinesq's mother died in 1857 and his father made it very clear that his duty was to take over the running of the family farm. His only route was to defy his father's wishes, and to study his favourite subject of mathematics without family support. He managed this by taking employment as a housemaster without teaching duties at the Lycée de Montpellier, while he studied languages and mathematics at the Faculty of Sciences at Montpellier. He was awarded a Bachelor's degree in mathematics in 1861.

Having been awarded a degree which qualified him to teach in secondary schools, Boussinesq followed a teaching career being appointed to the Lycée in Agde in 1862, that in Le Vigan in 1865, then in Gap in 1866. These towns are all in the south of France: Agde is, like the town in which Boussinesq was born, in Hérault - in fact it is on the river Hérault, 4 km from the Mediterranean Sea; Le Vigan is 64 km north of Montpellier; but Gap is much further east - it is the capital of the Hautes-Alpes, about 800 metres above sea level on right bank of the Luye River. It was while teaching at the first of these schools in Agde that Boussinesq became drawn towards research in mathematics when he read two texts by Gabriel Lamé, namely Théorie mathématique de l'Elasticité and Leçons sur la théorie analytique de la chaleur . Inspired to undertake research, his first scientific paper on capillarity was presented to the Académie des Sciences by Lamé in 1865. He began working for a doctorate on A mechanical theory of light supervised by Émile Verdet. However, Verdet died in 1866 before Boussinesq's thesis was completed. He was then given another supervisor and, to suit his new supervisor's interests, Boussinesq changed the topic of his thesis and wrote Études sur la propagation de la chaleur dans les milieux homogènes . Lamé had played a major role in advising Boussinesq and the thesis clearly shows his influence in the way Boussinesq approached his subject. Another mathematician who influenced the work was Saint-Venant. The examining committee, however, comprised of Joseph Serret, Joseph Bertrand and Charles Auguste Briot and Boussinesq defended his thesis in Paris before this committee on 13 May 1867.

Boussinesq had not concentrated on his thesis to the exclusion of other research, for he had worked on the theory of linear elasticity at the same time. This topic was particularly fascinating to Saint-Venant who corresponded regularly with Boussinesq and gave him much encouragement to believe that he had a future as a research mathematician rather than as a school teacher of mathematics [5]:-
Boussinesq was not a lucid writer and was often too impatient in giving logical explanations so that, on several occasions, Saint-Venant advised him to give clear and detailed arguments in his work.
In fact from this time on Saint-Venant was Boussinesq's staunchest supporter and became even more influential in 1868 when he was elected to succeed Poncelet in the mechanics section of the Académie des Sciences. Boussinesq had married Jeanne Giscard de la Roque in 1867 and, but for Saint-Venant's support and advice, might well have settled down to teaching in secondary schools. Saint-Venant understood the system well and was able to advise Boussinesq that to obtain a university position in mechanics would be very difficult unless he had both a mathematics and a physics qualification. He followed this advice and in 1872 was awarded a Bachelor's degree in physics. The Académie des Sciences awarded him their Poncelet Prize in 1872 and he was well set up for a university appointment. Indeed he succeeded in the following year when he was appointed Professor of Differential and Integral Calculus at the Faculty of Science in Lille.

Boussinesq's research contributions up to this point had been very substantial. In addition to the research undertaken for his thesis, he had already published works such as Mémoire sur l'influence des frottements dans les mouvements réguliers des fluides (1868); Théorie de l'intumescence liquide appelée onde solitaire ou de translation, se propageant dans un canal rectangulaire (1871); Étude nouvelle sur l'équilibre et le mouvement des corps solides élastiques dont certaines dimensions sont très petites par rapport à d'autres. Premier mémoire : des tiges ; deuxième mémoire : des plaques planes (1871); Théorie des ondes et des remous qui se propagent le long d'un canal rectangulaire horizontal (1872); Théorie des ondes liquides périodiques (1872); and Sur les lois qui régissent, à une première approximation, les ondes lumineuses propagées dans un milieu homogène et transparent d'une contexture quelconque (1872). In fact Boussinesq gave the first mathematical treatment of the problem of the stability of solitary waves in the first of these 1871 papers. Darrigol writes [3]:-
... Boussinesq had been working on open-channel theory for some time. In the steps of his mentor Saint-Venant, he tried to subject every aspect of the motion of water in rivers and canals to mathematical analysis. He was aware of Russell's observations, and also of the more precise measurements of solitary waves performed by the French hydraulician Henry Bazin. He had already written a long memoir on water waves of small height on water of constant depth. In addition to results that could be found in earlier memoirs by Green, Kelland, and Airy (of which he was unaware), he offered a few preliminary considerations on waves of finite height that may have led him to reflect on Russell's wave. In his first derivation of the solitary wave, published in 1871 in the 'Comptes rendus', Boussinesq sought an approximate solution of Euler's equations that propagated at the constant speed c without deformation in a rectangular channel. His success in this difficult task depended on his special flair in estimating the relative importance of the various terms of his developments. His basic strategy was to develop the velocity components in powers of the vertical distance from the bottom of the channel, and to determine the coefficients of this development through the boundary conditions. Lagrange had already tried this route and written the resulting series of differential equations, but had found their integration to exceed the possibilities of contemporary analysis unless nonlinear terms were dropped. A century later Boussinesq managed to include these terms.
Boussinesq taught at Lille for about fifteen years during which he continued to make major contributions to a wide variety of areas of applied mathematics. In [6] Bois collects these under the following headings: The problem of static stresses in soils; Turbulent flows (first phase); Surface waves and Boussinesq's equation; The BBO equation and the 'historical term' of Basset-Boussinesq; and The method of potential, the 'Boussinesq problem' and the vibrations of bars. In addition he undertook research on light propagation and on philosophical aspects of science, topics on which he continued to work throughout his career. These outstanding contributions led to his appointment to Eugene Rolland's chair in the Académie des Sciences on 18 January 1886. A condition of this appointment was that Boussinesq move to Paris so he requested that he be given a transfer from the Faculty of Science in Lille to the Faculty of Science in Paris. This was agreed and he was appointed Professor of Physical and Experimental Mechanics at the Faculty of Science in Paris. Pierre-Antoine Bois writes [6]:-
Boussinesq was no dashing young man when he arrived in Paris at the beginning of 1886. He was a modest looking man. Saint-Venant, his former mentor, was not there to greet him because, by an unlucky stroke of fate, he who supported Boussinesq with so much perseverance from the start of his career in Agde up to the Academy of Sciences, had just died, on 6 January, at the age of 89, twelve days before his pupil's election. Upon arrival among his new colleagues, Boussinesq proceeded to write his former mentor's obituary, in collaboration with Alfred Flamant, Saint-Venant's second favorite disciple. Such events contributed to his further withdrawing into himself; his only distraction was his research and he started working even more relentlessly. Boussinesq remained Professor of Physical and Experimental Mechanics at the Sorbonne for ten years, until he inherited the more prestigious chair of Mathematical Physics and Theory of Probabilities, a position which he kept until his retirement in 1918 at the age of 76.
In Paris he made another study of turbulent flows, using experimental results due to Bazin and ideas due to Reynolds. This led him to make 'Boussinesq's hypothesis' which gained him considerable credit when it was later confirmed experimentally by Bazin. He also developed an analytical theory of heat and made what has been called the 'Boussinesq Approximation'. In the text Théorie analytique de la chaleur mise en harmonie avec la thermodynamique et avec la théorie mécanique de la lumière, Tome II : Refroidissement et échauffement par rayonnement. Conductibilité des tiges, lames et masses cristallines. Courants de convection. Théorie mécanique de la lumière (1903) he explained when his approximation held:-
One still had to observe that in most heat-induced motions of our heavy fluids, the volumes or densities are approximately conserved, although the corresponding variation of the weight of the unit of volume is actually the cause of the phenomena we are studying. One possibility stems from there: neglecting the variations of the density where they are not multiplied by the gravity g, while conserving its product by the gravity in the calculation.
He had already published a number of other important texts in such as Application des potentiels à l'étude de l'équilibre et du mouvement des solides élastiques (1885) while still in Lille, and, after moving to Paris: Cours d'analyse infinitésimale en vue de ses applications mécaniques et physiques (2 volumes) (1887 and 1890); Leçons synthétiques de Mécanique générale servant d'introduction au cours de Mécanique physique (1889); and Théorie analytique de la chaleur mise en harmonie avec la thermodynamique et avec la théorie mécanique de la lumière, Tome I : Problèmes généraux (1901).

Eight years after Boussinesq arrived in Paris, his wife Jeanne died; they had no children. In the following year, 1895, he married Claire Onfroy de Véretz. This marriage lasted for 10 years until Claire died in 1905. Boussinesq again married in the year following his wife's death, on this third occasion to Jeanne Le Bouteiller. This marriage only lasted for three years; they separated in 1909. In 1918, at the age of 76, he retired from his university positions [6]:-
Withdrawn by nature, he became more and more solitary. In his obituary in 1933, his colleague Émile Picard only talked about Boussinesq's last years as an academic. However, even academically, Picard stressed how introverted his colleague had been. ... Picard pointed out, however, that there was no bitterness in Boussinesq's solitude. Although shy and withdrawn, he never judged people severely. Every day, almost until the end, he would come to the library at the Academy and sit at the same table. That was his only link with the outside world.
As to Boussinesq's interests outside mathematics, these seem to have been mainly an interest in philosophical and religious problems [1]:-
... particularly on the conciliation of determinism and free will. He humbly admitted "the smallness of the ensemble of our unclouded knowledge is lost in an ocean of darkness."
Boussinesq's place in the development of mathematical physics is summed up by Félix as follows [1]:-
One of his conclusions was that simplicity is indispensable in scientific organisation and that intuition is a valuable guide. Boussinesq loathed the introduction of such monsters as continuous functions without derivatives and of non-Euclidean spaces. Hostile to relativistist innovations, he remained loyal to classical mechanics and the sure reality of the aether. ... By virtue of the spirit of his research he can be considered one of the last figure of classical science in the nineteenth century.


References (show)

  1. L Félix, Biography in Dictionary of Scientific Biography (New York 1970-1990). See THIS LINK.
  2. J D Anderson, A History of Aerodynamics (Cambridge Univ. Press, Cambridge, 1997).
  3. O Darrigol, Worlds of Flow: A History of Hydrodynamics from the Bernoullis to Prandtl (Oxford University Press, Oxford, 2005).
  4. E Picard, La vie et l'oeuvre de Joseph Boussinesq (Académie des Sciences, Discours et notices, Gauthier-Villars, Paris, 1933).
  5. S P Timoshenko, History of Strength of Materials: With a Brief Account of the History of Theory of Elasticity and Theory of Structures (McGraw-Hill, New York, 1953).
  6. P-A Bois, Joseph Boussinesq (1842-1929) : a pioneer of mechanical modelling at the end of the 19th Century, C. R. Mecanique 335 (2007), 479-495.
  7. M Parreau, Joseph-Valentin Boussinesq (1842-1929) (2004).
  8. F Schmitt, About Boussinesq's turbulent viscosity hypothesis: historical remarks and a direct evaluation of its validity, C. R. Mecanique 335 (2007).
  9. R K Zeytounian, Joseph Boussinesq and his Approximation: a contemporary view, C. R. Mecanique 331 (2003), 575-586.

Additional Resources (show)


Written by J J O'Connor and E F Robertson
Last Update April 2009