Toggle navigation
Higher Academic
Humanities and Social Science
Agriculture
Anthropology / Ethnography
Archaeology
Architecture
Biographies
Children's Books
Cookery
Culture Studies
Demography
Development Studies
Disha Books
Ecology
Economics
Education
English Language and Literature
Film & Media Studies
Geography
Health
History
Human Rights
Law
Literature in Translation
Migration Studies
OBS Atlas
Philosophy
Political Science
Religion
Social Science
Sociology
Women's Studies
Indian Languages
Hindi
Marathi
Kannada
Bangla
General Books and Reference
General Books
Reference
Science, Technology, Medicine and Management
Biotechnology
Computer Science
Business and Management
Engineering & Technology
Environment & Biodiversity
Mathematics
Physics and Chemistry
Popular Science
Medical and Paramedical
Test Preparation
School Education
eBooks
eBooks on kindle
kobo
nook
iBookStore (for overseas customers)
Events
About Us
Publish With Us
Contact Us
About Us
Our Company
Our Associates
Our Network
Social Responsibility
Act
Projects
Investors
Information for Shareholders
Annual Return Form MGT-7
Career
Login
×
Introduction to Representation Theory
Introduction to Representation Theory
Pavel Etingof , Oleg Golberg, Sebastian Hensel, Tiankai Liu, Alex Schwendner, Dmitry Vaintrob, Elena Yudovina
Price
1100.00
ISBN
9781470419196
Language
English
Pages
240
Format
Paperback
Dimensions
140 x 216 mm
Year of Publishing
2014
Series
American Mathematical Society
Territorial Rights
Restricted
Imprint
Universities Press
Catalogues
Mathematics
About the Book
About the Author
Table of Contents
Pavel Etingof , Oleg Golberg, Sebastian Hensel, Tiankai Liu, Alex Schwendner, Dmitry Vaintrob, Elena Yudovina, with historical interludes by Slava Gerovitch
Editorial Board
Gerld B. Folland Brad G. Osgood (Chair)
Robin Forman John Stillwell
Chapter 1. Introduction 1
Chapter 2. Basic notions of representation theory 5
2.1. What is representation theory? 5
2.2. Algebras 8
2.3. Representations 9
2.4. Ideals 15
2.5. Quotients 15
2.6. Algebras defined by generators and relations 16
2.7. Examples of algebras 17
2.8. Quivers 19
2.9. Lie algebras 22
2.10. Historical interlude: Sophus Lie’s trials and transformations 26
2.11. Tensor products 30
2.12. The tensor algebra 35
2.13. Hilbert’s third problem 36
2.14. Tensor products and duals of representations of Lie algebras 36
2.15. Representations of sl(2) 37
iii
iv Contents
2.16. Problems on Lie algebras 39
Chapter 3. General results of representation theory 41
3.1. Subrepresentations in semisimple representations 41
3.2. The density theorem 43
3.3. Representations of direct sums of matrix algebras 44
3.4. Filtrations 45
3.5. Finite dimensional algebras 46
3.6. Characters of representations 48
3.7. The Jordan-H¨older theorem 50
3.8. The Krull-Schmidt theorem 51
3.9. Problems 53
3.10. Representations of tensor products 56
Chapter 4. Representations of finite groups: Basic results 59
4.1. Maschke’s theorem 59
4.2. Characters 61
4.3. Examples 62
4.4. Duals and tensor products of representations 65
4.5. Orthogonality of characters 65
4.6. Unitary representations. Another proof of Maschke’s theorem for complex representations 68
4.7. Orthogonality of matrix elements 70
4.8. Character tables, examples 71
4.9. Computing tensor product multiplicities using character tables 74
4.10. Frobenius determinant 75
4.11. Historical interlude: Georg Frobenius’s “Principle of Horse Trade” 77
4.12. Problems 81
4.13. Historical interlude: William Rowan Hamilton’s quaternion of geometry, algebra, metaphysics, and poetry 86
Contents v
Chapter 5. Representations of finite groups: Further results 91
5.1. Frobenius-Schur indicator 91
5.2. Algebraic numbers and algebraic integers 93
5.3. Frobenius divisibility 96
5.4. Burnside’s theorem 98
5.5. Historical interlude: William Burnside and intellectual harmony in mathematics 100
5.6. Representations of products 104
5.7. Virtual representations 105
5.8. Induced representations 105
5.9. The Frobenius formula for the character of an induced representation 106
5.10. Frobenius reciprocity 107
5.11. Examples 110
5.12. Representations of Sn 110
5.13. Proof of the classification theorem for representations of Sn 112
5.14. Induced representations for Sn 114
5.15. The Frobenius character formula 115
5.16. Problems 118
5.17. The hook length formula 118
5.18. Schur-Weyl duality for gl(V ) 119
5.19. Schur-Weyl duality for GL(V ) 122
5.20. Historical interlude: Hermann Weyl at the intersection of limitation and freedom 122
5.21. Schur polynomials 128
5.22. The characters of L? 129
5.23. Algebraic representations of GL(V ) 130
5.24. Problems 131
5.25. Representations of GL2(Fq) 132
5.26. Artin’s theorem 141
vi Contents
5.27. Representations of semidirect products 142
Chapter 6. Quiver representations 145
6.1. Problems 145
6.2. Indecomposable representations of the quivers A1,A2,A3 150
6.3. Indecomposable representations of the quiver D4 154
6.4. Roots 160
6.5. Gabriel’s theorem 163
6.6. Reflection functors 164
6.7. Coxeter elements 169
6.8. Proof of Gabriel’s theorem 170
6.9. Problems 173
Chapter 7. Introduction to categories 177
7.1. The definition of a category 177
7.2. Functors 179
7.3. Morphisms of functors 181
7.4. Equivalence of categories 182
7.5. Representable functors 183
7.6. Adjoint functors 184
7.7. Abelian categories 186
7.8. Complexes and cohomology 187
7.9. Exact functors 190
7.10. Historical interlude: Eilenberg, Mac Lane, and “general abstract nonsense” 192
Chapter 8. Homological algebra 201
8.1. Projective and injective modules 201
8.2. Tor and Ext functors 203
Chapter 9. Structure of finite dimensional algebras 209
9.1. Lifting of idempotents 209
9.2. Projective covers 210
Contents vii
9.3. The Cartan matrix of a finite dimensional algebra 211
9.4. Homological dimension 212
9.5. Blocks 213
9.6. Finite abelian categories 214
9.7. Morita equivalence 215
References for historical interludes 217
Mathematical references 223
Index 225