Alexander Grothendieck’s biography with his major mathematical contributions

A concise quote from an http://www-groups.dcs.st-andrews.ac.uk/ history/Biographies/Grothendieck.htmlarticle by J J O’Connor and E F Robertson is:

“Alexander Grothendieck’s father was Russian and he (Alex’s father) was murdered by the Nazis.”

… (His mother, Hanka Grothendieck, was German); …“Grothendieck moved to France in 1941 and later entered Montpellier University. After graduating from Montpellier he spent the year 1948-49 at the $\mathrm{É}$cole Normale Sup$\mathrm{é}$rieure in Paris.”

…“people are accustomed to work with fundamental groups and generators and relations for these and stick to it, even in contexts when this is wholly inadequate, namely when you get a clear description by generators and relations only when working simultaneously with a whole bunch of base-points chosen with care - or equivalently working in the algebraic context of groupoids, rather than groups. Choosing paths for connecting the base points natural to the situation to one among them, and reducing the groupoid to a single group, will then hopelessly destroy the structure and inner symmetries of the situation, and result in a mess of generators and relations no one dares to write down, because everyone feels they won’t be of any use whatever, and just confuse the picture rather than clarify it. I have known such perplexity myself a long time ago, namely in Van Kampen type situations, whose only understandable formulation is in terms of (amalgamated sums of) groupoids.” by Alexander Grothendieck.

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  1949 Alex Grothendieck worked on functional analysis with Jean Dieudonn$\mathrm{é}$e at the University of Nancy in France; he was only for a short time one of the ‘Nicolas Bourbaki’ group (http://planetmath.org/NicolasBourbaki) of mathematicians that included at various times: Andr$\mathrm{é}$ Weil, Henri Cartan, Charles Ehresmann and Dieudonn$\mathrm{é}$e. A quote from http://www.ams.org/notices/200808/tx080800930p.pdf“Who Is Grothendieck ?”: “To begin with, (L) Schwartz gave Grothendieck a paper to read that he had just written with Dieudonn$é$e, which ended with a list of fourteen unsolved problems. After a few months, Grothendieck had solved all of them. Try to visualize the situation: on one side, Schwartz, who had just received a Fields Medal and was at the top of his scientific career, and on the other side the unknown student from the provinces, who had a rather inadequate and unorthodox education. Grothendieck was awarded a Ph.D. for his work on topological vector spaces and stuck with that field for a while.”

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  Alexander Grothendieck’s doctoral thesis supervised by his advisor Laurent Schwartz, and co-advised by Jean Dieudonn$\mathrm{é}$e was entitled “Produits tensoriels topologiques et espaces nucl$\mathrm{é}$aires”;

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  1953-1955 Visiting at the University of S$\mathrm{ã}$o Paulo, supported by the Centre National de la R$\mathrm{é}$cherche Scientifique;

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  1956 Returned to France at the Centre National de la R$\mathrm{é}$cherche Scientifique;

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  1960: Visiting at the University of Kansas in the USA working on topology and geometry, supported by the Centre National de la Recherche Scientifique beginning with 1956.

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  1970-72 Visiting Professor at Coll$\mathrm{é}$ge de France.

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  1972-73 Visiting Professor at Orsay.

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  1973 Professor at the University of Montpellier.

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  1984-88 On leave– to direct research at the Centre National de la Recherche Scientifique.

1959-1970: Chair of the newly formed Institut des Hautes $\mathrm{É}$tudes Scientifiques (IHES); the IHES years have been referred to as his ‘Golden Age’, when an entire new school of Abstract Mathematics flourished under Grothendieck’s extremely creative leadership; thus, Grothendieck’s S$\mathrm{é}$minaire de G$\mathrm{é}$om$\mathrm{é}$trie Alg$\mathrm{è}$brique [8, 6] established IHES as the World’s Center of Algebraic Geometry during 1960-1970, with Alex as its driving force. He travelled widely across Europe, including the Soviet-occupied Eastern Europe (such as the invited visit he made in the Summer of 1968 when he delivered a lecture at the School of Mathematics in Bucharest at the invitation of Acad. Prof. Dr. Miron Nicolescu of the Romanian Academy (supported from 1866 by Prince Charles von Hohenzollern-Sigmaringen–who became in 1881–King Carol I of Romania), and across the World. Grothendieck is a very strong pacifist with very high ideals and goals, of real honesty and also extreme modesty; Alexander Grothendieck campaigned against the military built-up of the 1960s, which built-up almost ended up in total annihilation of our planet during the Cuban missile crisis.

Alexander Grothendieck’s work during the ‘Golden Age’ period established unifying themes in: Algebraic Geometry, Number theory, Topology, Category Theory and Functional/Complex Analysis. He introduced his own ‘theory of schemes’ in the 1960’s which allowed certain of A. Weil’s number theory conjectures to be solved. He worked on the theory of topoi/toposes that are relevant not only to mathematical logic and category theory, but also to computer software/programming and institutional ontology classification and bioinformatics. He provided an algebraic proof of the Riemann-Roch theorem, algebraic definition of the fundamental group of a curve, the definition of the fundamental functor for a categorical Galois theory, the re-definition of Abelian categories,(as for example in the case of $𝒜b5$ categories that carry his name-the Grothendieck and local Grothendieck categories), he outlined the ‘Dessins d’ Enfants’ combinatorial topology theory and much, much more. His “S$\text{é}m$inaires de G$\mathrm{é}$ometrie alg$\mathrm{è}$briques” alone are several thousands of pages in (typewritten) printed length, or close to 500 Mb in electronic format. Later in the ’80’s in his ‘Esquisse d’un Programme’ he outlined the ‘anabelian’ homology theory, what is called today in different fields by different names: Non-Abelian Homology Theory (that has not yet been achieved as he planned to do), non-Abelian Algebraic Topology, Noncommutative geometry, Non-Abelian Quantum Field theories, or ultimately, non-Abelian Categorical Ontology, fields that are still in need of future developments.

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  Speaker at the International Congress of Mathematicians in 1958;

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  Alexander Grothendieck received the Fields Medal in 1966, which he accepted;

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  Alexander Grothendieck was awarded, but declined, the Crafoord Prize in 1988; the prize was instead accepted by one of his http://www.genealogy.math.ndsu.nodak.edu/id.php?id=61289French former students;

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  Emeritus Professor in 1988 on his 60th birthday.

One was struck immediately upon meeting him by his generosity and the energy with which Alex shared his ideas with colleagues and students, as well as the excitement that he incited through his brilliantly clear lecturing style, thus inspiring others to share in his excitement for all of Mathematics, not just some highly specialized subject, as if they were ‘to set out to explore a completely new land, or white territory’.

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  Topological tensor products and nuclear spaces,

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  Sheaf cohomology as derived functors, schemes, K-theory and Grothendieck-Riemann-Roch,

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  Étale Cohomology and the Cohomological interpretation of L-functions,

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  Crystalline cohomology,

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  Defining and constructing geometric objects via Representable Functors,

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  Descent, fibred categories and stacks,

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  Grothendieck topologies (sites) and topoi,

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  Derived categories,

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  Formalisms for local and global duality (the ’six operations’),

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  Motives and the ’yoga of weights’,

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  Tensor Categories and Motivic Galois Groups.

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  Proofs of two generalized Riemann-Roch-Grothendieck theorems conjectured by André Weil.

Note: Alexander Grothendieck’s http://www.genealogy.math.ndsu.nodak.edu/id.php?id=31245&fChrono=1mathematical ‘genealogy’ is claimed to go back through many successive doctoral advisor generations from Laurent Schwartz to Borel, Darboux,…, Simeon Poisson, Joseph Lagrange, Leonhard Euler, Bernoulli, Gottfried Leibniz (in 1666, with a 53,763-long sequence of ‘descendants’), Weigel and Christiaan Huygens, and the record finally stops at Ludolph van Ceulen at the Universiteit Leiden in 1607 AD!

A most valuable resource in Algebraic Geometry, “Ho- and Coho- mology”: http://books.google.com/books?hl=en&id=FBfygannPSUC&dq=Alexandre+Grothendieck&printsec=frontcover&source=web&ots=Rwmt1x2weX&sig=y330F6qaDddY6_zyIJJA0SU602U&sa=X&oi=book_result&resnum=9&ct=resultGrothendieck-Serre Correspondence–Bilingual Edn.