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Anders Johan Lexell

Anders Johan Lexell (December 24, 1740 – December 11, 1784 (Julian calendar: November 30)) was a Swedish-born Russian astronomer, mathematician and physicist who spent most of his life in Russia where he is known as Andrei Ivanovich Leksel (Андрей Иванович Лексель).

Lexell made important discoveries in polygonometry and celestial mechanics, the latter led to a comet named in his honour. La Grande Encyclopédie states that he was the prominent mathematician of his time who contributed to the spherical trigonometry with new and interesting solutions, which he took as a basis for his research of comet and planet motion. His name was given to one of the theorems about spherical triangles.

Lexell was one of the most prolific members of the Russian Academy of Sciences at that time, having published 66 papers in 16 years of his work there. A statement attributed to Leonhard Euler expresses high approval of Lexell's works: "Besides Lexell, such a paper could only be written by D'Alambert or me".[1] Daniel Bernoulli also praised his work, writing in a letter to Johann Euler "I like Lexell's works, they are profound and interesting, and the value of them is increased even more because of his modesty, which adorns great men".[2]

Lexell did not have a family and keeped up close friendship with Leonhard Euler and his family. He witnessed Euler's death at his house and succeeded Euler to the chair of mathematics department at the Russian Academy of Sciences, but died the following year. The asteroid 2004 Lexell is named in his honour, as is the lunar crater Lexell.


Life

Early years

Anders Johan Lexell was born in Åbo to Johan Lexell, a local administrative officer, and Madeleine-Catherine Björkegren. At the age of fourteen he enrolled at the University of Åbo and in 1760 received his Doctor of Philosophy degree with a dissertation "Aphorismi mathematico-physici" (academic advisor Jakob Gadolin). In 1763 he moved to Uppsala and worked at Uppsala University as a mathematics lecturer, and since 1766 as a professor of mathematics at the Uppsala Nautical School.

St. Petersburg

In 1762 Catherine the Great came to the throne and started the politics of enlightened absolutism. She was aware of the importance of science and ordered to offer Leonhard Euler to "state his conditions, as soon as he moves to St. Petersburg without delay".[3] Soon after his return to Russia Leonhard Euler proposed to the director of the Russian Academy of Science to invite the mathematics professor Anders Johan Lexell to study mathematics and its application to astronomy, especially the spherical geometry. The invitation by Leonhard Euler and the preparations that were made at that time to observe the 1769 transit of Venus from eight locations in the vast Russian Empire made Lexell seek the opportunity to become a member of the St. Petersburg scientific community.

To be admitted to the Russian Academy of Sciences Lexell in 1768 wrote a paper on integral calculus calles "Methodus integrandi nonnulis aequationum exemplis illustrata". Academician Euler who was appointed to evaluate the paper highly praised it and Count Vladimir Orlov who was the Director of the Russian Academy of Sciences at that time sent the invitation to Lexell to take the position of mathematics adjunct, which Lexell willingly accepted. In the same year he got the permission from the Swedish king and immediately left for St. Petersburg.

His first occupation was getting used to the astronomical instruments to take part in the observations of transit of Venus which he did in 1769 in St. Petersburg together with Christian Mayer who was hired by the Academy to work at the observatory while the Russian astronomers went to other locations.

Lexell made big contribution to the Lunar theory and especially to determining the parallax of the Sun from the results of observations of the transit of Venus. He earned universal recognition and in 1771, when the Russian Academy of Sciences affiliated new members, Lexell was admitted as an Astronomy Academician. He was admitted to membership in Academy of Stockholm and Academy of Uppsala in 1773 and 1774, and became a corresponding member of the Paris Royal Academy of Sciences.

Foreign trip

In 1775 Swedish King appointed him to a chair of mathematics department at the University of Åbo with a permission to stay at St. Petersburg for another three years to finish his work there, this permission was later prolonged for two more years. Hence, in 1780 Lexell was supposed to leave St. Petersburg and return to Sweden, which would be a great loss for the Academy, if only director Domashnev not offered Lexell to go for a trip to Germany, England and France and then to return to St. Petersburg via Sweden. Lexell went on a trip and, to Academy's great pleasure, got a discharge from Swedish King and returned to St. Petersburg in 1781, after more than a year of absence, very satisfied with his trip.

Sending academicians abroad was quite rare at that time (as opposed to the early years of the Russian Academy of Sciences), so Lexell willingly agreed to go for a trip and was offered to write an instruction for himself which then without changes was signed by Domashnev. The aims were as follows: since Lexell would visit major observatories on his way, he should learn how they are built, note the number and types of scientific instruments used and if he finds something new and interesting he should buy the plans and design drawings. He should also learn everything about cartography and try to get new geographic, hydrographic, military and mineralogic maps. He should also write letters to the Academy regularly and to report interesting news on science, arts and literature[4].

Lexell left St. Petersburg in late July 1780 on a sailing ship and via Swinemünde arrived in Berlin, where he stayed for a month and traveled to Potsdam seeking in vain for an audience with king Frederick II. In September he left for Bavaria, visited Leipzig, Göttingen and Mannheim. In October via Strassburg he arrived in Paris, where he spent the winter, and in March 1781 moved to London. After spending three months in England in August he left for Belgium, where he visited Flanders and Brabant, then moved to Netherlands, visited The Hague, Amsterdam and Saardam and then returned to Germany in September. He visited Hamburg and then got aboard a ship in Kiel to sail to Sweden, he spent three days in Kopenhagen on the way. In Sweden he spent some time in his native city Åbo, also visited Stockholm, Uppsala and Åland Islands. In early December 1781 Lexell returned to St. Petersburg, after having travelled for almost a year and a half.

There are 28 letters in the archive of Russian Academy of Sciences that Lexell wrote during the trip to Johann Euler, while the official reports that Euler wrote to the Director of Academy Domashnev were lost. However, unofficial letters to Johann Euler often contain detailed descriptions of places and people Lexell met and his impressions.[5]

Last years

Lexell became very attached to Leonhard Euler, who lost sight in his last years but continued working using his elder son Johann Euler to read. Lexell helped Euler greatly, especially in applying mathematics to physics and astronomy. He helped Euler write down calculations and papers. On 18 September 1783, after a lunch with his family, during a conversation with Lexell about the newly discovered Uranus and its orbit Euler felt sick and died few hours later.[3]

The director of the Academy princess Dashkova appointed Lexell in 1783 to replace the late Leonhard Euler. Lexell became a corresponding member of the Turin Royal Academy, and London Board of Longitude put him on the list of scientists receiving its proceedings.

Lexell did not enjoy his position for long: he died in the evening on 30 November 1784.

Contribution to science

Lexell is mainly known for his works in astronomy and celestial mechanics, but he also worked in almost all areas of mathematics: algebra, differential calculus, integral calculus, geometry, analytic geometry, trigonometry, as well as continuum mechanics. Being a mathematician and working on the main problems of mathematics, he never missed the opportunity to look into specific problems in applied science, allowing for experimental proof of theory underlying the physical phenomenon. In 16 years of his work at Russian Academy of Sciences he published 62 works and 4 more with coauthors, among whom are Leonhard Euler, Johann Euler, Wolfgang Ludwig Krafft, Stephan Rumovski and Christian Mayer.

Differential equations

When applying for a position at the Russian Academy of Sciences Lexell submitted a paper called "Method of analysing some differential equations, illustrated with examples",[6] which was highly praised by Leonhard Euler in 1768. Lexell's method is as follows: for a given nonlinear differential equation (e.g. second order) we pick an intermediate integral - a first-order differential equation with undefined coefficients and exponents. After differentiating this intermediate integral we compare it with the original equation and get the equations for the coefficients and exponents of the intermediate integral. After we express the undetermined coefficients via the known coefficients we substitute them in the intermediate integral and get two particular solutions of the original equation. Subtracting one particular solution from another we get rid of the differentials and get a general solution, which we analyse at various values of constants. The method of reducing the order of the differential equation was known at that time, but in another form. Lexell's method was significant because it was applicable to a broad range of linear differential equations with constant coefficients that were important for physics applications. In the same year Lexell published another article "On integrating the differential equation andny + ban-1dm-1ydx + can-2dm-2ydx2 + ... + rndxn = Xdxn"[7] presenting a general highly algorithmic method of solving higher order linear differential equations with constant coefficients.

Lexell also looked for criteria of integrability of differential equations. He tried to find criteria for the whole differential equations and also for separate differentials. In 1770 he derived a criterion for integrating differential function, proved it for any number of items and found the integrability criteria for . His results agreed to those of Leonhard Euler but were more general and were derived without the means of calculus of variations. By special desire of Euler, Lexell in 1772 communicated these results to Lagrange[8] and Lambert.[9]

Concurrently with Euler, Lexell worked on expanding the integrating factor method to higher order differential equations. He developed the method of integrating differential equations with two or three variables by means of integrating factor. He stated that his method could be expanded for the case of four variables: "The formulas will be more complicated, while the problems leading to such equations are rare in analysis".[10]

Of great interest is also integration of differential equations done by Lexell in his paper "On reducing integral formulas to rectification of ellipses and hyperbolae",[11] which discusses elliptic integrals and their classification and in his paper "Integrating one differential formula with logarithms and circular functions",[12] which was reprinted in the transactions of the Swedish Academy of Sciences. He also integrated few complicated differential equation in his papers on continuum mechanics, including a four-order partial differential equation in a paper about coiling a flexible plate to a circular ring[13].

There is an unpublished Lexell's paper in the archive of Russian Academy of Sciences with a title "Methods of integration of some differential equations", in which a complete solution of the equation x = yφ(x') + ψ(x') now known as Lagrange-d'Alembert equation is presented.[14]

Polygonometry

Polygonometry was a significant part of Lexell's work. He used the trigonometrical approach using the advance in trigonometry made mainly by Euler and presented a general method of solving simple polygons in two articles "On solving rectilinear polygons"[15]. Lexell discussed two separate groups of problems: the first had the polygon defined by its sides and angles, the second - with its diagonals and angles between diagonals and sides. For the problems of the first group Lexell derived two general formulas giving n equations allowing to solve a polygon with n sides. Using these theorems he derived explicit formulas for triangles and tetragons and also gave formulas for pentagons, hexagons and heptagons. He also presented a classification of problems for tetragons, pentagons and hexagons. For the second group of problems Lexell showed that their solutions can be reduced to few general rules and presented a classification of these problems, solving the corresponding combinatorial problems. In the second article he applies his general method for specific tetragons and shows how to apply his method to a polygon with any number of sides , taking a pentagon as example.

The successor of Lexell's trigonometric approach (as opposed to coordinate one) was a Swiss mathematician L'Huillier. Both L'Huillier and Lexell emphasized the importance of polygonometry for theoretical and practical applications.

Celestial mechanics and astronomy

Lexell's first work at Russian Academy of Sciences was to analyse the data collected from the observation of the 1769 transit of Venus. He published four papers in "Novi Commentarii Academia Petropolitanae" and ended his work with a monograph on determining the parallax of the Sun published in 1772[16].

He also helped Euler finish his Lunar theory and was credited as a coauthor in Euler's 1772 "Theoria motuum Lunae"[17].

After that Lexell switched to comet astronomy (though his first paper on computing the orbit of a comet is dated 1770). In the next ten years he computed the orbits of all the newly discovered comets, among them the comet discovered in 1770 by Charles Messier. Lexell computed its orbit, showed that the comet had had a much larger perihelion before the encounter with Jupiter in 1767 and predicted that after encountering Jupiter again in 1779 it would be altogether expelled from the inner Solar System. This comet was later named after him as Lexell's Comet.

Lexell also was the first to compute the orbit of Uranus and to actually prove that it was a planet rather than a comet[18]. He made first computations when he was travelling in Europe in 1781 based on Hershel's and Maskelyne's observations. Having returned to Russia he computed the orbit more precisely based on new observations but due to the long orbital period it was still not enough data to prove that the orbit was not parabolic. Lexell then found the record of a star observed in 1759 by Christian Mayer in Pisces that was neither in the Flamsteed catalogues nor at the sky by the time Bode sought it. Lexell presumed that it was an earlier sighting of the same astronomical object and using this data he calculated the exact orbit, which proved to be elliptical, and proved that the new object was actually a planet. In addition to calculating the parameters of the orbit Lexell also estimated the planet's size more precisely than his contemporaries using Mars that was in the vicinity of the new planet at that time. Lexell also noticed that the orbit of Uranus was being perturbed. He then stated that, based on his data on various comets, the size of the Solar system can be 100 A.U. or even more, and that it could be other planets there that perturb the orbit of Uranus (although the position of the eventual Neptune was not calculated until much later by Urbain Le Verrier).

References and notes

1. ^ "Precis de la vie de M. Lexell". Nova Acta Academia Scientarum Imperialis Petropolitanae 2: 16–18. 1784.
2. ^ Uchenaya Korrespondentsiya 62 (48). 24.02.1776.
3. ^ a b A. Ya. Yakovlev (1983). Leonhard Euler. Moscow: Prosvesheniye.
4. ^ "Voyage Académique". Acta Academia Scientarum Imperialis Petropolitanae (2): 109–110. 1780.
5. ^ Lubimenko, Inna (1936). "The foreign trip of Academician A. J. Lexell in 1780-1781". Archiv Istorii Nauki i Techniki 8: 327–358.
6. ^ A. J. Lexell (1769). "Methodus integrandi nonnulis aequationum differentialum exemplis illustrata". Novi Commentarii Academia Scientarum Imperialis Petropolitanae 14 (1): 238–248.
7. ^ A. J. Lexell (1769). "De integratione aequationis differentialis andny + ban-1dm-1ydx + can-2dm-2ydx2 + ... + rydxn = Xdxn". Novi Commentarii Academia Scientarum Imperialis Petropolitanae 14 (1): 215–237.
8. ^ Lagrange J. L. (1862). Oeuvres. 3. Paris.
9. ^ Bopp K. (1924). "Leonhard Eulers und Johann Heinrich Lamberts Briefwechsel". Abh. Preuss. Akad. Wiss. 2: 38–40.
10. ^ A. J. Lexell (1772). "De criteriis integrabilitatis formularum differentialium: Dissertatio secunda". Novi Commentarii Academia Scientarum Imperialis Petropolitanae 16: 171–229.
11. ^ A. J. Lexell (1778). "De reductione formularum integralium ad rectificationem ellipseos et hyperbolae". Acta Academia Scientarum Imperialis Petropolitanae (1): 58–101.
12. ^ A. J. Lexell (1785). "Integratio formulae cuiusdam differentialis per logarithmos et arcus circulares". Nova Acta Academia Scientarum Imperialis Petropolitanae 3: 104–117.
13. ^ A. J. Lexell (1785). "Meditateones de formula qua motus laminarium elasticarum in annulos circulares incurvatarum exprimitur". Acta Academia Scientarum Imperialis Petropolitanae (2): 185–218.
14. ^ V. I. Lysenko (1990). "Differential equations in the works of A. I. Leksel". Istoriko-Matematicheskie Issledovaniya (Moscow: Nauka) (32-33).
15. ^ A. J. Lexell (1774). "De resolutione polygonorum rectilineorum. Dissertiatio prima.". Novi Commentarii Academia Scientarum Imperialis Petropolitanae 19: 184–236. ,A. J. Lexell (1775). "De resolutione polygonorum rectilineorum. Dissertiatio secunda.". Novi Commentarii Academia Scientarum Imperialis Petropolitanae 20: 80–122.
16. ^ A. J. Lexell (1772). Disquisitio de investiganda vera quantitate parallaxeos solis, et transitu Veneris ante discum solis anno 1769, cui accedunt anumadversiones in tractatum rev. pat. Hell de parallaxi solis. pp. 131.
17. ^ J. A. Euler, W. L. Krafft, J. A. Lexell (1772). Theoria motuum lunae, nova methodo pertractata una cum tabulis astronomicis, und ad quodvis tempus loca lunae expedite computari possunt, incredibili studio atque indefesso labore trium Academicorum: Johannis Alberti Euler, Wolffgangi Ludovici Kraft, Johannis Andreae Lexel. Opus dirigente Leonardo Eulero.. pp. 775.
18. ^ A. J. Lexell (1783). "Recherches sur la nouvelle planete, decouverte par M. Herschel & nominee Georgium Sidus". Acta Academia Scientarum Imperialis Petropolitanae (1): 303–329.

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