DOCSLIB.ORG

Prof. Alexander Grothendieck - the Math Genius! - 11-19-2014 by Gonit Sora - Gonit Sora

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Prof. Alexander Grothendieck - the Math Genius! - 11-19-2014 by Gonit Sora - Gonit Sora Prof. Alexander Grothendieck - The math genius! - 11-19-2014 by Gonit Sora - Gonit Sora - https://gonitsora.com Prof. Alexander Grothendieck - The math genius! by Gonit Sora - Wednesday, November 19, 2014 https://gonitsora.com/prof-alexander-grothendieck-math-genius/ I was reading a math-related post in Facebook when suddenly the message icon in the top right corner of the facebook page turned red and the speakers of my system made a beep sound. It was a message from my friend, Manjil, asking me to write an obituary of the famous mathematician Alexander Grothendieck. I immediately replied "Yes of course!". Incidentally, the math-related post I mentioned in the first line was a news report on the recent death of the same math genius. I opened an extra tab on my browser and searched for more details about Prof. Grothendieck. And yes, I was shocked to see a huge bunch of info about him on various sites. So, I realised that writing about him is going to be tough! Ultimately I have come up with a brief write up on the life and works of Prof. Grothendieck. I, on behalf of GonitSora, dedicate this write up to the revolutionary mathematician Prof. Alexander Grothendieck. May his soul rest in peace! Alexander Grothendieck Prof. Grothendeick was a French mathematician and the leading figure in creating modern algebraic geometry. His research program vastly extended the scope of the field, incorporating major elements of commutative algebra, homological algebra, sheaf theory, and category theory into its foundations. This new perspective led to revolutionary advances across many areas of pure mathematics. Born in Germany on 28th March 1928, Grothendieck was raised and lived primarily in France. Being a Jew, he did not have a happy childhood and he also had to bear the pathetic sufferings in the Nazi concentration camps. In 1933 Alexander's parents moved to Paris to escape the Nazis, leaving their five year old son with a family in Hamburg, where he went to school. Unfortunately, Alexander never really knew his father but even then he held him in great esteem. His office at the Institut des Hautes Études Scientifiques (IHES ) (French for "Institute of Advanced Scientific Studies") had no decoration except a portrait of his father. In 1945, Grothendieck and his mother moved to the village of Maisargues near Montpellier, where he worked in the vineyards and also, with the aid of a small scholarship, studied mathematics at the University of Montpellier. As a student, Alexander became fascinated with mathematics at a young age but he was not ready to take everything for granted. While at school he had felt dissatisfied with some of the mathematics that had been presented to him. He once remarked What was least satisfying to me in our high school mathematics books was the absence of any serious definition of the notion of length of a curve, of area of a surface, of volume of a solid. I promised myself I would fill this gap when I had the chance. This clearly reflects his passion for understanding mathematics better. He was very dissatisfied with the teaching he was receiving. He had been told how to compute the volume of a sphere or a pyramid, but no one had explained the definition of volume. It is an unmistakable sign of a mathematical spirit to want to 1 / 4 Prof. Alexander Grothendieck - The math genius! - 11-19-2014 by Gonit Sora - Gonit Sora - https://gonitsora.com replace the "how" with a "why". One of his professors assured him that a certain Lebesgue had resolved the last outstanding problems in mathematics, but that his work would be too difficult to teach. Alone, with almost no hints, Grothendieck rediscovered a very general version of the Lebesgue integral. Grothendieck was very hard working. He had very few books of his own. Such was his genius that rather than learning things by reading, he would try to reconstruct them on his own. with Jean-Pierre After graduating from Montpellier, he spent the year 1948-49 at the École Normale Supérieure in Paris. There he attended Henri Cartan's seminar on algebraic topology and sheaf theory and he came to contact with leading mathematicians like Claude Chevalley, Jean Delsarte, Jean Dieudonné, Roger Godement, Laurent Schwartz, and André Weil. One of Grothendieck's fellow students was Jean-Pierre Serre, the first Abel Laureate (2003). Since Grothendieck was at this time more interested in topological vector spaces than he was in algebraic topology, André Weil and Henri Cartan both advised him to go to Nancy where there was a strong team including Jean Dieudonné, Jean Delsarte, Roger Godement and Laurent Schwartz. In 1949 Grothendieck moved to the University of Nancy where he lived with his mother. At Nancy there was an active seminar every Saturday in which all the professors and some of the students used to participate to discuss a variety of different topics. It provided a wonderful environment for the young Grothendieck. Grothendieck presented his doctoral thesis Produits tensoriels topologiques et espaces nucleaires (Topological tensor products and nuclear spaces) in 1953. He spent the years 1953-55 at the University of Sao Paulo and then he spent the following year at the University of Kansas. It was during this period that his research interests changed and they moved towards topology and geometry. During this period Grothendieck had been supported by the Centre National de la Recherche Scientifique, the support beginning in 1950. After leaving Kansas in 1956 he therefore returned to the Centre National de la Recherche Scientifique. Around this time, he became one of the Bourbaki group of mathematicians which included André Weil, Henri Cartan and Jean Dieudonné. In 1959 he was offered a research position in the newly formed Institut des Hautes Études Scientifiques (IHES) which he accepted. The years 1959-70 that Grothendieck spent at the IHES can be termed as a 'Golden Age', during which a whole new school of mathematics flourished under his charismatic leadership. Grothendieck's Séminaire de Géométrie Algébrique established the IHES as a world centre of algebraic geometry, and him as its driving force. During this period Grothendieck's work provided unifying themes in geometry, number theory, topology and complex analysis. He introduced the theory of schemes in the 1960s which allowed certain of Weil's number theory conjectures to be solved. He worked on the theory of topoi which are highly relevant to mathematical logic. He gave an algebraic proof of the Riemann-Roch theorem. He provided an algebraic definition of the fundamental group of a curve. Luc Illusie, one of his PhD students, writes He spoke with great energy at the board but taking care to recall all the necessary material. He was very precise. The presentation was so neat that even I, who knew nothing of the topic, could understand the formal structure. It was going fast but so clearly that I could take notes. Grothendieck's best known contributions are found in a wide variety of topics which include topological 2 / 4 Prof. Alexander Grothendieck - The math genius! - 11-19-2014 by Gonit Sora - Gonit Sora - https://gonitsora.com tensor products and nuclear spaces, sheaf cohomology as derived functors, schemes, K-theory and Grothendieck-Riemann-Roch, the emphasis on working relative to a base, defining and constructing geometric objects via the functors they are to represent, fibred categories and descent, stacks, Grothendieck topologies (sites) and topoi, derived categories, formalisms of local and global duality (the 'six operations'), étale cohomology and the cohomological interpretation of L-functions, crystalline cohomology, 'standard conjectures', motives and the 'yoga of weights', tensor categories and motivic Galois groups. This list reflects his exceptional mathematical talent. Prof. Grothendieck was also a person of great kindness and generosity. He seemed always to be in good spirits, with great mental equilibrium. He possessed a miraculous capacity for work. In 1966, he received the Fields Medal which is the highest award in the mathematical arena. The citation for the Fields Medal read Grothendieck built on work of Weil and Zariski and effected fundamental advances in algebraic topology. He introduced the idea of K-theory (the Grothendieck groups and rings). He revolutionised homological algebra in his celebrated `Tohoko paper. The `Tohoko paper' referred to in this citation is about abelian categories, sheaves of modules, resolutions, derived functors, and the Grothendieck spectral sequence. The Fields Medal is presented every year at the International Congress of Mathematicians (ICM) and in 1966 the ICM was was held in Moscow, Russia. Mathematicians, in general, keep themselves outside politics but Grothendieck was a bit different. Grothendieck was always strongly pacifist in his views and he had campaigned against the military built-up of the 1960s and hence as a political protest, he refused to travel to Moscow to receive the Fields medal. At the Congress, Léon Motchane, director of IHES, received the Fields Medal on Grothendieck's behalf. Grothendieck made no public statement about the reasons for not going to Moscow but he declared himself a citizen of the world and requested United Nations citizenship. Prof. Grothendeick left the IHES in 1970 after he discovered that some of their funding came from military sources. He discovered this in 1969 and, along with the other professors at the IHES, he persuaded the director, Léon Motchane, to take no further funding from the French military. However, a few months later the IHES faced a financial crisis and the director went back on his word. Grothendieck tried to persuade all the professors to resign in protest but the others refused to follow his example. Grothendieck's letter of resignation was dated 25 May 1970.
Load more

Recommended publications
  • Tōhoku Rick Jardine
    INFERENCE / Vol. 1, No. 3 Tōhoku Rick Jardine he publication of Alexander Grothendieck’s learning led to great advances: the axiomatic description paper, “Sur quelques points d’algèbre homo- of homology theory, the theory of adjoint functors, and, of logique” (Some Aspects of Homological Algebra), course, the concepts introduced in Tōhoku.5 Tin the 1957 number of the Tōhoku Mathematical Journal, This great paper has elicited much by way of commen- was a turning point in homological algebra, algebraic tary, but Grothendieck’s motivations in writing it remain topology and algebraic geometry.1 The paper introduced obscure. In a letter to Serre, he wrote that he was making a ideas that are now fundamental; its language has with- systematic review of his thoughts on homological algebra.6 stood the test of time. It is still widely read today for the He did not say why, but the context suggests that he was clarity of its ideas and proofs. Mathematicians refer to it thinking about sheaf cohomology. He may have been think- simply as the Tōhoku paper. ing as he did, because he could. This is how many research One word is almost always enough—Tōhoku. projects in mathematics begin. The radical change in Gro- Grothendieck’s doctoral thesis was, by way of contrast, thendieck’s interests was best explained by Colin McLarty, on functional analysis.2 The thesis contained important who suggested that in 1953 or so, Serre inveigled Gro- results on the tensor products of topological vector spaces, thendieck into working on the Weil conjectures.7 The Weil and introduced mathematicians to the theory of nuclear conjectures were certainly well known within the Paris spaces.
    [Show full text]
  • Fundamental Algebraic Geometry
    http://dx.doi.org/10.1090/surv/123 hematical Surveys and onographs olume 123 Fundamental Algebraic Geometry Grothendieck's FGA Explained Barbara Fantechi Lothar Gottsche Luc lllusie Steven L. Kleiman Nitin Nitsure AngeloVistoli American Mathematical Society U^VDED^ EDITORIAL COMMITTEE Jerry L. Bona Peter S. Landweber Michael G. Eastwood Michael P. Loss J. T. Stafford, Chair 2000 Mathematics Subject Classification. Primary 14-01, 14C20, 13D10, 14D15, 14K30, 18F10, 18D30. For additional information and updates on this book, visit www.ams.org/bookpages/surv-123 Library of Congress Cataloging-in-Publication Data Fundamental algebraic geometry : Grothendieck's FGA explained / Barbara Fantechi p. cm. — (Mathematical surveys and monographs, ISSN 0076-5376 ; v. 123) Includes bibliographical references and index. ISBN 0-8218-3541-6 (pbk. : acid-free paper) ISBN 0-8218-4245-5 (soft cover : acid-free paper) 1. Geometry, Algebraic. 2. Grothendieck groups. 3. Grothendieck categories. I Barbara, 1966- II. Mathematical surveys and monographs ; no. 123. QA564.F86 2005 516.3'5—dc22 2005053614 Copying and reprinting. Individual readers of this publication, and nonprofit libraries acting for them, are permitted to make fair use of the material, such as to copy a chapter for use in teaching or research. Permission is granted to quote brief passages from this publication in reviews, provided the customary acknowledgment of the source is given. Republication, systematic copying, or multiple reproduction of any material in this publication is permitted only under license from the American Mathematical Society. Requests for such permission should be addressed to the Acquisitions Department, American Mathematical Society, 201 Charles Street, Providence, Rhode Island 02904-2294, USA.
    [Show full text]
  • Cartan and Complex Analytic Geometry
    Cartan and Complex Analytic Geometry Jean-Pierre Demailly effort in France to recruit teachers, due to the much increased access of pupils and students to On the Mathematical Heritage of Henri higher education, along with a strong research ef- Cartan fort in technology and science. I remember quite Henri Cartan left us on August 13, 2008, at the well that my father had a book with a mysterious age of 104. His influence on generations of math- title: Théorie Élémentaire des Fonctions Analytiques ematicians worldwide has been considerable. In d’une ou Plusieurs Variables Complexes (Hermann, France especially, his role as a 4th edition from 1961) [Ca3], by Henri Cartan, professor at École Normale Su- which contained magical stuff such as contour périeure in Paris between 1940 integrals and residues. I could then, of course, and 1965 led him to supervise not understand much of it, but my father was the Ph.D. theses of Jean-Pierre quite absorbed with the book; I was equally im- Serre (Fields Medal 1954), René pressed by the photograph of Cartan on the cover Thom (Fields Medal 1958), and pages and by the style of the contents, which had many other prominent math- obvious similarity to the “New Math” we started ematicians such as Pierre Cart- being taught at school—namely set theory and ier, Jean Cerf, Adrien Douady, symbols like ∪, ∩, ∈, ⊂,... My father explained Roger Godement, Max Karoubi, to me that Henri Cartan was one of the leading and Jean-Louis Koszul. French mathematicians and that he was one of However, rather than rewrit- the founding members of the somewhat secre- ing history that is well known tive Bourbaki group, which had been the source to many people, I would like of inspiration for the new symbolism and for the here to share lesser known reform of education.
    [Show full text]
  • Armand Borel 1923–2003
    Armand Borel 1923–2003 A Biographical Memoir by Mark Goresky ©2019 National Academy of Sciences. Any opinions expressed in this memoir are those of the author and do not necessarily reflect the views of the National Academy of Sciences. ARMAND BOREL May 21, 1923–August 11, 2003 Elected to the NAS, 1987 Armand Borel was a leading mathematician of the twen- tieth century. A native of Switzerland, he spent most of his professional life in Princeton, New Jersey, where he passed away after a short illness in 2003. Although he is primarily known as one of the chief archi- tects of the modern theory of linear algebraic groups and of arithmetic groups, Borel had an extraordinarily wide range of mathematical interests and influence. Perhaps more than any other mathematician in modern times, Borel elucidated and disseminated the work of others. family the Borel of Photo courtesy His books, conference proceedings, and journal publica- tions provide the document of record for many important mathematical developments during his lifetime. By Mark Goresky Mathematical objects and results bearing Borel’s name include Borel subgroups, Borel regulator, Borel construction, Borel equivariant cohomology, Borel-Serre compactification, Bailey- Borel compactification, Borel fixed point theorem, Borel-Moore homology, Borel-Weil theorem, Borel-de Siebenthal theorem, and Borel conjecture.1 Borel was awarded the Brouwer Medal (Dutch Mathematical Society), the Steele Prize (American Mathematical Society) and the Balzan Prize (Italian-Swiss International Balzan Foundation). He was a member of the National Academy of Sciences (USA), the American Academy of Arts and Sciences, the American Philosophical Society, the Finnish Academy of Sciences and Letters, the Academia Europa, and the French Academy of Sciences.1 1 Borel enjoyed pointing out, with some amusement, that he was not related to the famous Borel of “Borel sets." 2 ARMAND BOREL Switzerland and France Armand Borel was born in 1923 in the French-speaking city of La Chaux-de-Fonds in Switzerland.
    [Show full text]
  • PDF Generated By
    8 The Functional Role of Structures in Bourbaki Gerhard Heinzmann and Jean Petitot 1. Introduction From antiquity to the 19th century and even up to now, the following two theses are among the most debated in the philosophy of mathematics: a) According to the Aristotelian tradition, mathematical objects such as num- bers, quantities, and figures are entities belonging to different kinds. b) Mathematical objects are extralinguistic entities that exist, independently of our representations, in an abstract world. They are conceived by analogy with the physical world and designated by singular terms of a mathemat- ical language. The Aristotelian thesis and that of ontological “Platonism” were countered by nominalism and early tendencies of algebraic formalization; but they became even more problematic when mathematicians, such as Niels Abel, thought of re- lations before their relata or when they, as Hermann Hankel (1867) pointed out, posited that mathematics is a pure theory of forms whose purpose is not that of treating quantities or combinations of numbers (see Bourbaki 1968, 317). In the 1930s, Bourbaki finally defended the view that mathematics does not deal with traditional mathematical objects at all, but that objectivity is solely based on the stipulation of structures and their development in a hierarchy. In the history of 20th- century mathematical structuralism, the figure of Bourbaki is prominent; sometimes he is even identified with the philosoph- ical doctrine of structuralism. However, the Bourbaki group consisted of pure mathematicians— among them the greatest of their generation—most of whom had a conflicted relationship to philosophy. This chapter proposes to explore this tension, following the current philosophical interest in scientific practice.
    [Show full text]
  • Twenty-Five Years with Nicolas Bourbaki, 1949-1973
    Twenty-Five Years with Nicolas Bourbaki, 1949–1973 Armand Borel he choice of dates is dictated by per- To set the stage, I shall briefly touch upon the sonal circumstances: they roughly bound first fifteen years of Bourbaki. They are fairly well the period in which I had inside knowl- documented2, and I can be brief. edge of the work of Bourbaki, first In the early thirties the situation of mathemat- through informal contacts with several ics in France at the university and research levels, T the only ones of concern here, was highly unsat- members, then as a member for twenty years, until the mandatory retirement at fifty. isfactory. World War I had essentially wiped out one Being based largely on personal recollections, generation. The upcoming young mathematicians my account is frankly subjective. Of course, I had to rely for guidance on the previous one, in- checked my memories against the available docu- cluding the main and illustrious protagonists of the mentation, but the latter is limited in some ways: so-called 1900 school, with strong emphasis on not much of the discussions about orientation and analysis. Little information was available about current developments abroad, in particular about general goals has been recorded.1 Another mem- the flourishing German school (Göttingen, Ham- ber might present a different picture. burg, Berlin), as some young French mathemati- cians (J. Herbrand, C. Chevalley, A. Weil, J. Leray) Armand Borel is professor emeritus at the School of Math- were discovering during visits to those centers.3 ematics, Institute for Advanced Study, Princeton, NJ.
    [Show full text]
  • The Life of Alexandre Grothendieck, Volume 51, Number 9
    Comme Appelé du Néant— As If Summoned from the Void: The Life of Alexandre Grothendieck Allyn Jackson This is the first part of a two-part article about the life of Alexandre Grothendieck. The second part of the article will appear in the next issue of the Notices. Et toute science, quand nous l’enten- the Institut des Hautes Études Scientifiques (IHÉS) dons non comme un instrument de pou- and received the Fields Medal in 1966—suffice to voir et de domination, mais comme secure his place in the pantheon of twentieth cen- aventure de connaissance de notre es- tury mathematics. But such details cannot capture pèce à travers les âges, n’est autre chose the essence of his work, which is rooted in some- que cette harmonie, plus ou moins vaste thing far more organic and humble. As he wrote in et plus ou moins riche d’une époque à his long memoir, Récoltes et Semailles (Reapings and l’autre, qui se déploie au cours des Sowings, R&S), “What makes the quality of a re- générations et des siècles, par le délicat searcher’s inventiveness and imagination is the contrepoint de tous les thèmes apparus quality of his attention to hearing the voices of tour à tour, comme appelés du néant. things” (emphasis in the original, page P27). Today Grothendieck’s own voice, embodied in his written And every science, when we understand works, reaches us as if through a void: now seventy- it not as an instrument of power and six years old, he has for more than a decade lived domination but as an adventure in in seclusion in a remote hamlet in the south of knowledge pursued by our species France.
    [Show full text]
  • Chapter 7 Nicolas Bourbaki: Theory of Structures
    Chapter 7 Nicolas Bourbaki: Theory of Structures The widespread identification of contemporary mathematics with the idea of structure has often been associated with the identification of the structural trend in mathematics with the name of Nicolas Bourbaki. Fields medalist René Thom, in a famous polemical article concerning modern trends in mathemati- cal education, asserted that Bourbaki “undertook the monumental task of reor- ganizing mathematics in terms of basic structural components.”1 Thom further claimed that: Contemporary mathematicians, steeped in the ideas of Bourbaki, have had the natural tendency to introduce into secondary and university courses the algebraic theories and structures that have been so useful in their own work and that are uppermost in the mathematical thought of today. (Thom 1971, 695) The identification of Bourbaki with modern, structural mathematics is not always as explicitly formulated as in Thom’s quotation, but it has interestingly been manifest in many other ways. Thus for instance, during the years 1956 and 1957 in Paris the “Association des professeurs de mathématiques de l'enseignement public” organized in Paris two cycles of lectures for its mem- bers. The lectures, meant to present high-school teachers with an up-to-date picture of the discipline, were delivered by such leading French mathemati- cians as Henri Cartan, Jacques Dixmier, Roger Godement, Jean-Pierre Serre, and several others. They were later collected into a volume entitled Algebraic Structures and Topological Structures.2 Thus we have the first component of the two-fold identification: “up-to-date mathematics = structural mathemat- ics.” The second component—“Bourbaki’s structures = mathematical struc- tures”—was not explicitly articulated therein, yet the editors made this second identification plain and clear by choosing to conclude the book with a motto 1.
    [Show full text]
  • Death of a Schoolmaster
    NEWSLETTER OF THE EUROPEAN MATHEMATICAL SOCIETY ERCOM Feature History Interview MPI-Leipzig Chaotic vibrations Edinburgh Math Soc Pierre Cartier p. 35 p. 19 p. 27 p. 31 December 2009 Issue 74 ISSN 1027-488X S E European M M Mathematical E S Society ems Dec_09.qxp 24/11/2009 08:39 Page 1 MaMathemathematicstics Book Bookss 1 FROMFROM OO XFXF ORDORD Introduction to Applied Algebraic Oxford University Press is pleased to announce that all Systems EMS members can benefit from a 20% discount on a large Norman R Reilly range of our Mathematics books. For more information This upper level undergraduate textbook please visit: www.oup.com/uk/sale/science/ems provides a modern view of algebra with an eye to new applications that have arisen in recent years. NEW ! 2009 | 524 pp | Hardback |978-0-19-536787-4| £50.00 The Oxford Handbook of Membrane Computing EMS member price: £40.00 Edited by Gheorghe Paun, Grzegorz Rozenberg and Arto Salomaa Thermoelasticity with Finite Wave Provides both a comprehensive survey Speeds of available knowledge and established Józef Ignaczak and Martin Ostoja Starzewski research topics, and a guide to recent Extensively covers the mathematics of developments in the field, covering the two leading theories of hyperbolic subject from theory to applications. thermoelasticity: the Lord Shulman Dec. 2009 | 696 pp | Hardback |978-0-19-955667-0 | £85.00 theory, and the Green Lindsay theory. EMS member price: £68.00 Oxford Mathematical Monographs NEW ! Oct. 2009 | 432 pp | Hardback |978-0-19-954164-5 | £70.00 Solitons, Instantons, and Twistors EMS member price: £56.00 Maciej Dunajski Provides a self contained and accessible introduction to elementary twistor Differential Equations with Linear theory; a technique for solving Algebra differential equations in applied Matthew R.
    [Show full text]
  • The Rising Sea: Grothendieck on Simplicity and Generality I
    The Rising Sea: Grothendieck on simplicity and generality I Colin McLarty 24 May 2003 In 1949 Andr´eWeil published striking conjectures linking number theory to topology, and sketched a topological strategy for a proof. Around 1953 Jean-Pierre Serre took on the project and soon recruited Alexander Grothendieck. Serre created a series of concise elegant tools which Grothendieck and coworkers simplified into thousands of pages of category theory. Miles Reid, for example, says “Grothendieck himself can’t necessarily be blamed for this since his own use of categories was very successful in solving problems” [Reid 1990, p. 116]. Here we focus on methods Grothendieck established by 1958: Abelian categories for derived functor cohomol- ogy, and schemes. We touch on toposes and ´etalecohomology which arose around 1958 as the context for the work. Grothendieck describes two styles in mathematics. If you think of a theorem to be proved as a nut to be opened, so as to reach “the nourishing flesh protected by the shell”, then the hammer and chisel principle is: “put the cutting edge of the chisel against the shell and strike hard. If needed, begin again at many different points until the shell cracks—and you are satisfied”. He says: I can illustrate the second approach with the same image of a nut to be opened. The first analogy that came to my mind is of immersing the nut in some softening liquid, and why not simply water? From time to time you rub so the liquid penetrates better, and otherwise you let time pass. The shell becomes more flexible through weeks and months—when the time is ripe, hand pressure is enough, the shell opens like a perfectly ripened avocado! A different image came to me a few weeks ago.
    [Show full text]
  • Armand Borel
    Armand Borel Jan Coufal1 Armand Borel (* 21 May 1923, La Chaux-de-Fonds, Swiss – + 11 August 2003, Princeton, New Jersey, USA) was a Swiss mathematician, attended secondary school in Geneva but was also educated at a number of private schools. In 1942, at the age of nineteen, he entered the École Polytechnique Fédérale in Zürich where he studied mathematics and physics. After completing military service, which was compulsory in Switzerland, he graduated with a diploma in mathematics in 1947 having undertaken his master's studies under Eduard Stiefel. As well as Stiefel, Borel had attended lectures at the École Polytechnique Fédérale by Hopf who played an important role in influencing Borel's mathematical tastes. Following his graduation, Borel was appointed as a teaching assistant at the École Polytechnique Fédérale in Zürich. His aim was to undertake research for his thesis on Lie groups and during his two years as a teaching assistant he published two papers on the topic. However, receiving an exchange grant from the French Centre National de la Recherche Scientifique he was able to spend the year 1949-50 in Paris. This was extremely important for him for he was able to get to know, and to learn from, Henri Cartan, Jean Dieudonné, and Laurent Schwartz. He made friends with younger mathematicians, Roger Godement, Pierre Samuel, Jacques Dixmier, and especially with Jean-Pierre Serre. Jean Leray became Borel's thesis supervisor and he attended courses which he gave at the Collège de France. Borel wrote [6]: All these people – the elder ones, of course, but also the younger ones – were very broad in their outlook.
    [Show full text]
  • Recoltes Et Semailles to the Printer
    Récoltes et Semailles, Part I The life of a mathematician Reflections and Bearing Witness Alexander Grothendieck 1986 English Translation by Roy Lisker Begun December 13, 2002 By way of a Preface ..... written January 30th, 1986 Only the preface remains before sending Recoltes et Semailles to the printer. And I confess that I had every intention of writing something appropriate . Something quite reasonable, for once. No more than 3 or 4 pages, yet well expressed, as a way of opening this enormous tome of over a thousand pages. Something that would hook the skeptical reader, that would make him willing to see what there was to be found in these thousand pages. Who knows, there may well be things here which might concern him personally! Yet that's not exactly my style, to hook people. But I was willing to make an exception in this case, just this once! It was essential if this book was to find an "editor crazy enough to undertake the venture" , ( of publishing this clearly unpublishable monster). Oh well, it's not my way. But I did my best. And not in a single afternoon, as I'd originally intended. Tomorrow it will be three weeks I've been at work on it, that I've watched the pages pile up. What has emerged can't in any sense be called a "preface" . Well, I've failed again. At my age I can't make myself over: I'm not made to be bought and sold! Even if I had every intention of being pleasing, to others and to myself ..
    [Show full text]