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Fundamental Theorems in Mathematics
SOME FUNDAMENTAL THEOREMS IN MATHEMATICS OLIVER KNILL Abstract. An expository hitchhikers guide to some theorems in mathematics. Criteria for the current list of 243 theorems are whether the result can be formulated elegantly, whether it is beautiful or useful and whether it could serve as a guide [6] without leading to panic. The order is not a ranking but ordered along a time-line when things were writ- ten down. Since [556] stated “a mathematical theorem only becomes beautiful if presented as a crown jewel within a context" we try sometimes to give some context. Of course, any such list of theorems is a matter of personal preferences, taste and limitations. The num- ber of theorems is arbitrary, the initial obvious goal was 42 but that number got eventually surpassed as it is hard to stop, once started. As a compensation, there are 42 “tweetable" theorems with included proofs. More comments on the choice of the theorems is included in an epilogue. For literature on general mathematics, see [193, 189, 29, 235, 254, 619, 412, 138], for history [217, 625, 376, 73, 46, 208, 379, 365, 690, 113, 618, 79, 259, 341], for popular, beautiful or elegant things [12, 529, 201, 182, 17, 672, 673, 44, 204, 190, 245, 446, 616, 303, 201, 2, 127, 146, 128, 502, 261, 172]. For comprehensive overviews in large parts of math- ematics, [74, 165, 166, 51, 593] or predictions on developments [47]. For reflections about mathematics in general [145, 455, 45, 306, 439, 99, 561]. Encyclopedic source examples are [188, 705, 670, 102, 192, 152, 221, 191, 111, 635]. -
Introduction to Representation Theory by Pavel Etingof, Oleg Golberg
Introduction to representation theory by Pavel Etingof, Oleg Golberg, Sebastian Hensel, Tiankai Liu, Alex Schwendner, Dmitry Vaintrob, and Elena Yudovina with historical interludes by Slava Gerovitch Licensed to AMS. License or copyright restrictions may apply to redistribution; see http://www.ams.org/publications/ebooks/terms Licensed to AMS. License or copyright restrictions may apply to redistribution; see http://www.ams.org/publications/ebooks/terms Contents Chapter 1. Introduction 1 Chapter 2. Basic notions of representation theory 5 x2.1. What is representation theory? 5 x2.2. Algebras 8 x2.3. Representations 9 x2.4. Ideals 15 x2.5. Quotients 15 x2.6. Algebras defined by generators and relations 16 x2.7. Examples of algebras 17 x2.8. Quivers 19 x2.9. Lie algebras 22 x2.10. Historical interlude: Sophus Lie's trials and transformations 26 x2.11. Tensor products 30 x2.12. The tensor algebra 35 x2.13. Hilbert's third problem 36 x2.14. Tensor products and duals of representations of Lie algebras 36 x2.15. Representations of sl(2) 37 iii Licensed to AMS. License or copyright restrictions may apply to redistribution; see http://www.ams.org/publications/ebooks/terms iv Contents x2.16. Problems on Lie algebras 39 Chapter 3. General results of representation theory 41 x3.1. Subrepresentations in semisimple representations 41 x3.2. The density theorem 43 x3.3. Representations of direct sums of matrix algebras 44 x3.4. Filtrations 45 x3.5. Finite dimensional algebras 46 x3.6. Characters of representations 48 x3.7. The Jordan-H¨oldertheorem 50 x3.8. The Krull-Schmidt theorem 51 x3.9. -
Graduate Studies Texas Tech University
77 75 G-7S 74 GRADUATE STUDIES TEXAS TECH UNIVERSITY Men and Institutions in American Mathematics Edited by J. Dalton Tarwater, John T. White, and John D. Miller K C- r j 21 lye No. 13 October 1976 TEXAS TECH UNIVERSITY Cecil Mackey, President Glenn E. Barnett, Executive Vice President Regents.-Judson F. Williams (Chairman), J. Fred Bucy, Jr., Bill E. Collins, Clint Form- by, John J. Hinchey, A. J. Kemp, Jr., Robert L. Pfluger, Charles G. Scruggs, and Don R. Workman. Academic Publications Policy Committee.-J. Knox Jones, Jr. (Chairman), Dilford C. Carter (Executive Director and Managing Editor), C. Leonard Ainsworth, Harold E. Dregne, Charles S. Hardwick, Richard W. Hemingway, Ray C. Janeway, S. M. Kennedy, Thomas A. Langford, George F. Meenaghan, Marion C. Michael, Grover E. Murray, Robert L. Packard, James V. Reese, Charles W. Sargent, and Henry A. Wright. Graduate Studies No. 13 136 pp. 8 October 1976 $5.00 Graduate Studies are numbered separately and published on an irregular basis under the auspices of the Dean of the Graduate School and Director of Academic Publications, and in cooperation with the International Center for Arid and Semi-Arid Land Studies. Copies may be obtained on an exchange basis from, or purchased through, the Exchange Librarian, Texas Tech University, Lubbock, Texas 79409. * Texas Tech Press, Lubbock, Texas 16 1976 I A I GRADUATE STUDIES TEXAS TECH UNIVERSITY Men and Institutions in American Mathematics Edited by J. Dalton Tarwater, John T. White, and John D. Miller No. 13 October 1976 TEXAS TECH UNIVERSITY Cecil Mackey, President Glenn E. Barnett, Executive Vice President Regents.-Judson F. -
The Role of GH Hardy and the London Mathematical Society
View metadata, citation and similar papers at core.ac.uk brought to you by CORE provided by Elsevier - Publisher Connector Historia Mathematica 30 (2003) 173–194 www.elsevier.com/locate/hm The rise of British analysis in the early 20th century: the role of G.H. Hardy and the London Mathematical Society Adrian C. Rice a and Robin J. Wilson b,∗ a Department of Mathematics, Randolph-Macon College, Ashland, VA 23005-5505, USA b Department of Pure Mathematics, The Open University, Milton Keynes MK7 6AA, UK Abstract It has often been observed that the early years of the 20th century witnessed a significant and noticeable rise in both the quantity and quality of British analysis. Invariably in these accounts, the name of G.H. Hardy (1877–1947) features most prominently as the driving force behind this development. But how accurate is this interpretation? This paper attempts to reevaluate Hardy’s influence on the British mathematical research community and its analysis during the early 20th century, with particular reference to his relationship with the London Mathematical Society. 2003 Elsevier Inc. All rights reserved. Résumé On a souvent remarqué que les premières années du 20ème siècle ont été témoins d’une augmentation significative et perceptible dans la quantité et aussi la qualité des travaux d’analyse en Grande-Bretagne. Dans ce contexte, le nom de G.H. Hardy (1877–1947) est toujours indiqué comme celui de l’instigateur principal qui était derrière ce développement. Mais, est-ce-que cette interprétation est exacte ? Cet article se propose d’analyser à nouveau l’influence d’Hardy sur la communauté britannique sur la communauté des mathématiciens et des analystes britanniques au début du 20ème siècle, en tenant compte en particulier de son rapport avec la Société Mathématique de Londres. -
Proofs from the BOOK
Martin Aigner · Günter M. Ziegler Proofs from THE BOOK Fifth Edition Martin Aigner Günter M. Ziegler Proofs from THE BOOK Fifth Edition Martin Aigner Günter M. Ziegler Proofs from THE BOOK Fifth Edition Including Illustrations by Karl H. Hofmann 123 Martin Aigner Günter M. Ziegler Freie Universität Berlin Freie Universität Berlin Berlin, Germany Berlin, Germany ISBN978-3-662-44204-3 ISBN978-3-662-44205-0(eBook) DOI 10.1007/978-3-662-44205-0 © Springer-Verlag Berlin Heidelberg 2014 This work is subject to copyright. All rights are reserved, whether the whole or part of the material is concerned, specifically the rights of translation, reprinting, reuse of illustrations, recitation, broadcasting, reproduction on microfilm or in any other way, and storage in data banks. Duplication of this publication or parts thereof is permitted only under the provisions of the German Copyright Law of September 9, 1965, in its current version, and permission for use must always be obtained from Springer. Violations are liable to prosecution under the German Copyright Law. The use of general descriptive names, registered names, trademarks, etc. in this publication does not imply, even in the absence of a specific statement, that such names are exempt from the relevant protective laws and regulations and therefore free for general use. Coverdesign: deblik, Berlin Printed on acid-free paper Springer is Part of Springer Science+Business Media www.springer.com Preface Paul Erdos˝ liked to talk about The Book, in which God maintains the perfect proofs for mathematical theorems, following the dictum of G. H. Hardy that there is no permanent place for ugly mathematics. -
Arxiv:2105.07884V3 [Math.HO] 20 Jun 2021
Enumerative and Algebraic Combinatorics in the 1960's and 1970's Richard P. Stanley University of Miami (version of 17 June 2021) The period 1960{1979 was an exciting time for enumerative and alge- braic combinatorics (EAC). During this period EAC was transformed into an independent subject which is even stronger and more active today. I will not attempt a comprehensive analysis of the development of EAC but rather focus on persons and topics that were relevant to my own career. Thus the discussion will be partly autobiographical. There were certainly deep and important results in EAC before 1960. Work related to tree enumeration (including the Matrix-Tree theorem), parti- tions of integers (in particular, the Rogers-Ramanujan identities), the Redfield- P´olya theory of enumeration under group action, and especially the repre- sentation theory of the symmetric group, GL(n; C) and some related groups, featuring work by Georg Frobenius (1849{1917), Alfred Young (1873{1940), and Issai Schur (1875{1941), are some highlights. Much of this work was not concerned with combinatorics per se; rather, combinatorics was the nat- ural context for its development. For readers interested in the development of EAC, as well as combinatorics in general, prior to 1960, see Biggs [14], Knuth [77, §7.2.1.7], Stein [147], and Wilson and Watkins [153]. Before 1960 there are just a handful of mathematicians who did a sub- stantial amount of enumerative combinatorics. The most important and influential of these is Percy Alexander MacMahon (1854-1929). He was a arXiv:2105.07884v3 [math.HO] 20 Jun 2021 highly original pioneer, whose work was not properly appreciated during his lifetime except for his contributions to invariant theory and integer parti- tions. -
Geometry at Cambridge, 1863–1940 ✩
View metadata, citation and similar papers at core.ac.uk brought to you by CORE provided by Elsevier - Publisher Connector Historia Mathematica 33 (2006) 315–356 www.elsevier.com/locate/yhmat Geometry at Cambridge, 1863–1940 ✩ June Barrow-Green, Jeremy Gray ∗ Centre for the History of the Mathematical Sciences, Faculty of Mathematics and Computing, The Open University, Milton Keynes, MK7 6AA, UK Available online 10 January 2006 Abstract This paper traces the ebbs and flows of the history of geometry at Cambridge from the time of Cayley to 1940, and therefore the arrival of a branch of modern mathematics in Great Britain. Cayley had little immediate influence, but projective geometry blossomed and then declined during the reign of H.F. Baker, and was revived by Hodge at the end of the period. We also consider the implications these developments have for the concept of a school in the history of mathematics. © 2005 Published by Elsevier Inc. Résumé L’article retrace les hauts et le bas de l’histoire de la géométrie à Cambridge, du temps de Cayley jusqu’à 1940. Il s’agit donc de l’arrivée d’une branche de mathématiques modernes en Grande-Bretagne. Cayley n’avait pas beaucoup d’influence directe, mais la géométrie projective fut en grand essor, déclina sous le règne de H.F. Baker pour être ranimée par Hodge vers la fin de notre période. Nous considérons aussi brièvement l’effet que tous ces travaux avaient sur les autres universités du pays pendant ces 80 années. © 2005 Published by Elsevier Inc. MSC: 01A55; 01A60; 51A05; 53A55 Keywords: England; Cambridge; Geometry; Projective geometry; Non-Euclidean geometry ✩ The original paper was given at a conference of the Centre for the History of the Mathematical Sciences at the Open University, Milton Keynes, MK7 6AA, UK, 20–22 September 2002. -
Proofs from the BOOK
Martin Aigner · Günter M. Ziegler Proofs from THE BOOK Sixth Edition Martin Aigner Günter M. Ziegler Proofs from THE BOOK Sixth Edition Martin Aigner Günter M. Ziegler Proofs from THE BOOK Sixth Edition Including Illustrations by Karl H. Hofmann 123 Martin Aigner Günter M. Ziegler Institut für Mathematik Institut für Mathematik Freie Universität Berlin Freie Universität Berlin Berlin, Germany Berlin, Germany ISBN 978-3-662-57264-1 ISBN 978-3-662-57265-8 (eBook) https://doi.org/10.1007/978-3-662-57265-8 Library of Congress Control Number: 2018940433 © Springer-Verlag GmbH Germany, part of Springer Nature 1998, 2001, 2004, 2010, 2014, 2018 This work is subject to copyright. All rights are reserved by the Publisher, whether the whole or part of the material is concerned, specifically the rights of translation, reprinting, reuse of illustrations, recitation, broadcasting, reproduction on microfilms or in any other physical way, and transmission or information storage and retrieval, electronic adaptation, computer software, or by similar or dissimilar methodology now known or hereafter developed. The use of general descriptive names, registered names, trademarks, service marks, etc. in this publication does not imply, even in the absence of a specific statement, that such names are exempt from the relevant protective laws and regulations and therefore free for general use. The publisher, the authors and the editors are safe to assume that the advice and information in this book are believed to be true and accurate at the date of publication. Neither the publisher nor the authors or the editors give a warranty, express or implied, with respect to the material contained herein or for any errors or omissions that may have been made. -
William Vallance Douglas Hodge. 17 June 1903
WILLIAM VALLANCE DOUGLAS HODGE 17 June 1903 - 7 July 1975 Elected F.R.S. 1938 BY M. F. ATIYAH,F.R.S. SIRWILLIAM HODGE, formerly Lowndean Professor of Astronomy and Geometry in the University of Cambridge, Master of Pembroke College, Cambridge, and Physical Secretary of the Royal Society, was for over forty years a leading figure in British mathematical life. He died in July 1975 at the age of 72. EARLY LIFE Hodge came from a moderately prosperous Edinburgh background, but it appears that on both sides of the family this prosperity only went back a couple of generations and that his two grandfathers had been responsible for raising the social level, from rather humble origins, to a modest middle-class standing in the last quarter of the nineteenth century. The paternal grandfather, Archibald Hodge, spent most of his life in a firm, Douglas and Company, of Searchers of Records. This business, peculiar to Scotland, involved the examination of land titles and its fortunes were closely linked with those of the property market. In due course Archibald Hodge became senior partner of the firm and his only son Archibald James Hodge joined as junior partner. The other grandfather, William Vallance, built up a flourishing confectionery business which eventually had valuable premises in the centre of Edinburgh. His wife Janet (born Horsburgh) appears to have been the dominating partner both in the business and in the family. In spite of having eight children she remained in command of the business until her husband's death in 1903. Her eldest son then took over but was required to inform her daily on how things were going. -
The Life and Work of Major Percy Alexander Macmahon Paul Garcia
The life and work of Major Percy Alexander MacMahon PhD Thesis by Dr Paul Garcia History of Mathematics Thesis submitted to the Open University in fulfilment of the Degree of Doctor of Philosophy The life and work of Major Percy Alexander MacMahon Paul Garcia B.A. (Hons), MSc (Mathematics), MSc (Information and Knowledge Technology) May 2006 1 The life and work of Major Percy Alexander MacMahon PhD Thesis by Dr Paul Garcia Abstract This thesis describes the life and work of the mathematician Major Percy Alexander MacMahon (1854 - 1929). His early life as a soldier in the Royal Artillery and events which led to him embarking on a career in mathematical research and teaching are dealt with in the first two chapters. Succeeding chapters explain the work in invariant theory and partition theory which brought him to the attention of the British mathematical community and eventually resulted in a Fellowship of the Royal Society, the presidency of the London Mathematical Society, and the award of three prestigious mathematical medals and four honorary doctorates. The development and importance of his recreational mathematical work is traced and discussed. MacMahon’s career in the Civil Service as Deputy Warden of the Standards at the Board of Trade is also described. Throughout the thesis, his involvement with the British Association for the Advancement of Science and other scientific organisations is highlighted. The thesis also examines possible reasons why MacMahon’s work, held in very high regard at the time, did not lead to the lasting fame accorded to some of his contemporaries. Details of his personal and social life are included to give a picture of MacMahon as a real person working hard to succeed in a difficult context. -
Confirmation for Wielandt's Conjecture
Confirmation for Wielandt’s conjecture∗ Wenbin Guo Department of Mathematics, University of Science and Technology of China, Hefei 230026, P. R. China E-mail: [email protected] D. O. Revin, E. P. Vdovin Sobolev Institute of Mathematics and Novosibirsk State University, Novosibirsk 630090, Russia E-mail: [email protected], [email protected] Abstract Let π be a set of primes. By H.Wielandt definition, Sylow π-theorem holds for a finite group G if all maximal π-subgroups of G are conjugate. In the paper, the following statement is proven. Assume that π is a union of disjoint subsets σ and τ and a finite group G possesses a π-Hall subgroup which is a direct product of a σ- subgroup and a τ-subgroup. Furthermore, assume that both the Sylow σ-theorem and τ-theorem hold for G. Then the Sylow π-theorem holds for G. This result confirms a conjecture posed by H. Wielandt in 1959. Key words: finite group, Hall subgroup, Sylow π-theorem, condition Dπ, Wie- landt’s conjecture. MSC2010: 20D20 Introduction In the paper, the term ‘group’ always means ‘finite group’, p is always supposed to be a prime, π is a subset of the set of all primes, and π′ is its complement in the set of all primes. Lagrange’s theorem states that the order |G| of a group G is divisible by the order of arXiv:1407.2007v1 [math.GR] 8 Jul 2014 every subgroup of G. This simple statement has extraordinary significance and largely determines the problems of finite group theory. -
The Breadth-Degree Type of a Finite $ P $-Group
THE BREADTH-DEGREE TYPE OF A FINITE p-GROUP NORBERTO GAVIOLI, AVINOAM MANN, AND VALERIO MONTI Abstract. In the present paper we show that a stem finite p-group G has − − − size bounded by min p(8d 2 log2 d+b 4)(b+1)/2,pb(3b+4d 1)/2 where b is the breadth of G and pd is the maximum character degree of G. As a conse- quence there are only finitely many finite stem p-groups having breadth b and maximum character degree pd. Introduction The problem of finding all finite groups of a given order is quite old. In the case of finite p-groups (where p is a prime number) the task is particularly hard as the number of isomorphism classes grows rapidly with the order. This particular difficulty led Philip Hall, aiming at achieving a systematic classification theory, as he himself writes in his famous paper [12], to introduce the concept of isoclinism, an equivalence relation among groups preserving the commutation structure. A group T such that its center Z(T ) is contained in the derived subgroup T ′ is said to be a stem group. Philip Hall showed that finite stem groups are exactly the ones of minimum order within an isoclinism class. He also pointed out that the ratio of the number of conjugacy classes of a given size of a finite group G with respect to the order of G is preserved by isoclinism. In [12] it is also stated that the ratio of the number of irreducible characters of G of a given degree with respect to the order of G is invariant under isoclinism.