Introduction to Arithmetic Groups Preliminary version (February 27, 2003) Send comments to [email protected] Dave Witte Morris Department of Mathematics Oklahoma State University Stillwater, Oklahoma 74078, USA E-mail address: [email protected], http://www.math.okstate.edu/~dwitte Copyright (cid:1)c 2001, 2002, 2003 Dave Witte Morris. All rights reserved. Permission to make copies of these lecture notes for educational or scientific use, including multiple copies for classroom or seminar teaching, is granted (without fee), provided that any fees charged for the copies are only sufficient to recover the reasonable copying costs, and that all copies include this title page and its copyright notice. Specific written permission of the author is required to reproduce or distribute this book (in whole or in part) for profit or commercial advantage. Acknowledgments In writing this book, I have benefited from the comments and suggestions of many colleagues, including Marc Burger, Indira Chatterjee, Alessandra Iozzi, Anders Karlsson, Sean Keel, Nicolas Monod, Hee Oh, Yehuda Shalom, Shmuel Weinberger, Barak Weiss, and Kevin Whyte. I have also benefited greatly from discussions with Scot Adams, S.G. Dani, Benson Farb, G.A. Margulis, Gopal Prasad, M.S. Raghunathan, T. N. Venkataramana, and Robert J. Zimmer. They (and others) may note that some of the comments they made to me over the years have been reproduced here almost verbatim. I would like to thank E´. Ghys, D. Gaboriau and the other members of the E´cole Normale Sup´erieure de Lyon for the stimulating conversations and invitation to speak that were the impetus for this work, and B. Farb, A. Eskin and the other members of the University of Chicago math- ematics department for encouraging me to write this introduction, for the opportunity to lecture from it, and for providing a stimulating audience. I am grateful to ENS–Lyon, the University of Bielefeld, the Isaac Newton Institute for Math- ematical Sciences, and the Tata Institute for Fundamental Research for their warm hospitality while various of the chapters were being written. The preparation of this manuscript was partially supported by a research grant from the National Science Foundation (DMS–0100438). iii List of Chapters (Only 1–11, 25, and App. I are available so far) Acknowledgments iii Chapter 1. What is a Locally Symmetric Space? 1 Chapter 2. Geometer’s Introduction to R-rank and Q-rank 14 Chapter 3. Introduction to Semisimple Lie Groups 19 Chapter 4. Some of the Structure of Semisimple Lie Groups 32 Chapter 5. Basic Properties of Lattices 44 Chapter 6. What is an Arithmetic Lattice? 68 Chapter 7. Examples of Lattices 88 Chapter 8. Real Rank 112 Chapter 9. Q-Rank 121 Chapter 10. Arithmetic Lattices in Classical Groups 135 Chapter 11. Central division algebras over number fields 164 Chapter 12. Galois Cohomology and Q-Forms 173 Chapter 13. Lattices of Extremal Q-rank 175 Chapter 14. Fundamental Domain for G/GZ 179 Chapter 15. Arithmetic Subgroups are Lattices 181 Chapter 16. Zassenhaus Neighborhood 182 Chapter 17. Rigidity, Strong Rigidity and Superrigidity 183 Chapter 18. Root Systems 189 iv Preliminary version (February 27, 2003) List of Chapters(Only 1–11, 25, and App. I are available so farv) Chapter 19. Basic Properties of Semisimple Algebraic k-Groups 193 Chapter 20. Amenability vs. Kazhdan’s Property (T) 194 Chapter 21. Introduction to Ergodic Theory 200 Chapter 22. Proof of the Margulis Superrigidity Theorem 204 Chapter 23. Normal Subgroups of Higher-Rank Lattices 207 Chapter 24. Cohomology of Arithmetic Lattices 216 Chapter 25. Actions on the Circle 218 Appendix I. Assumed Background 250 List of Notation 262 Index 263 Contents Acknowledgments iii Chapter 1. What is a Locally Symmetric Space? 1 §1A. Symmetric spaces 1 §1B. How to construct a symmetric space 3 §1C. Locally symmetric spaces 6 §1D. Notes 9 §1E. References 10 Exercises 10 Chapter 2. Geometer’s Introduction to R-rank and Q-rank 14 §2A. Rank and real rank 14 §2B. Q-rank 15 §2C. Notes 18 §2D. References 18 Exercises 18 Chapter 3. Introduction to Semisimple Lie Groups 19 §3A. The standing assumptions 19 §3B. Isogenies 19 §3C. What is a semisimple Lie group? 20 §3D. The simple Lie groups 22 §3E. Which classical groups are isogenous? 24 §3F. Notes 28 §3G. References 28 Exercises 28 Chapter 4. Some of the Structure of Semisimple Lie Groups 32 §4A. G is almost Zariski closed 32 §4B. Real Jordan decomposition 34 vi Preliminary version (February 27, 2003) Contents vii §4C. Jacobson-Morosov Lemma 35 §4D. Maximal compact subgroups and the Iwasawa decomposition 35 §4E. Cartan involution and Cartan decomposition 36 §4F. The image of the exponential map 36 §4G. Parabolic subgroups 37 §4H. The normalizer of G 39 §4I. Fundamental group and center of G 40 §4J. Notes 40 §4K. References 40 Exercises 41 Chapter 5. Basic Properties of Lattices 44 §5A. Definition 44 §5B. Commensurability 46 §5C. Irreducible lattices 47 §5D. Unbounded subsets of Γ\G 48 §5E. Intersection of Γ with other subgroups of G 50 §5F. Borel Density Theorem and some consequences 51 §5G. Proof of the Borel Density Theorem 52 §5H. Γ is finitely presented 54 §5I. Γ has a torsion-free subgroup of finite index 56 §5J. Γ has a nonabelian free subgroup 59 §5K. Notes 62 §5L. References 63 Exercises 63 Chapter 6. What is an Arithmetic Lattice? 68 §6A. Definition of arithmetic lattices 68 §6B. Margulis Arithmeticity Theorem 71 §6C. Commensurability criterion for arithmeticity 73 §6D. Why superrigidity implies arithmeticity 73 §6E. Unipotent elements of GZ: the Godement Compactness Criterion 75 §6F. How to make an arithmetic lattice 76 §6G. Restriction of scalars 78 §6H. Notes 83 §6I. References 83 Exercises 84 Chapter 7. Examples of Lattices 88 §7A. Arithmetic lattices in SL(2,R) 88 §7B. Teichmu¨ller space and moduli space of lattices in SL(2,R) 91 §7C. Arithmetic lattices in SO(1,n) 92 viii Preliminary version (February 27, 2003) Contents §7D. Some nonarithmetic lattices in SO(1,n) 94 §7E. Noncocompact lattices in SL(3,R) 101 §7F. Cocompact lattices in SL(3,R) 103 §7G. Lattices in SL(n,R) 106 §7H. Quaternion algebras over a field F 107 §7I. Notes 108 §7J. References 108 Exercises 108 Chapter 8. Real Rank 112 §8A. R-split tori 112 §8B. Definition of real rank 113 §8C. Relation to geometry 114 §8D. Parabolic subgroups 115 §8E. Groups of real rank zero 115 §8F. Groups of real rank one 116 §8G. Groups of higher real rank 118 §8H. Notes 120 §8I. References 120 Exercises 120 Chapter 9. Q-Rank 121 §9A. Q-split tori 121 §9B. Q-rank of an arithmetic lattice 122 §9C. Isogenies over Q 124 §9D. Q-rank of any lattice 125 §9E. The possible Q-ranks 125 §9F. Lattices of Q-rank zero 126 §9G. Lattices of Q-rank one 128 §9H. Lattices of higher Q-rank 128 §9I. Parabolic Q-subgroups 129 §9J. The large-scale geometry of Γ\X 131 §9K. Notes 133 §9L. References 133 Exercises 134 Chapter 10. Arithmetic Lattices in Classical Groups 135 §10A. Complexification of G 135 §10B. Calculating the complexification of G 137 §10C. Cocompact lattices in some classical groups 139 §10D. Isotypic classical groups have irreducible lattices 141 §10E. What is a central division algebra over F? 146 Preliminary version (February 27, 2003) Contents ix §10F. What is an absolutely simple group? 148 §10G. Absolutely simple classical groups 149 §10H. The Lie group corresponding to each F-group 151 §10I. The arithmetic lattices in classical groups 152 §10J. What are the possible Hermitian forms? 154 §10K. Notes 160 §10L. References 160 Exercises 160 Chapter 11. Central division algebras over number fields 164 §11A. How to construct central division algebras over number fields 164 §11B. The Brauer group 167 §11C. Division algebras are cyclic 169 §11D. Simple algebras are matrix algebras 170 §11E. Cohomological approach to division algebras 171 §11F. Notes 172 §11G. References 172 Exercises 172 Chapter 12. Galois Cohomology and Q-Forms 173 §12A. Using Galois Cohomology to find the F-forms of classical groups 173 §12B. The Tits Classification 174 §12C. Inner forms and outer forms 174 §12D. Quasi-split groups 174 §12E. References 174 Exercises 174 Chapter 13. Lattices of Extremal Q-rank 175 §13A. Construction using Galois cohomology 175 §13B. Explicit construction of the Lie algebra 176 §13C. Notes 178 §13D. References 178 Exercises 178 Chapter 14. Fundamental Domain for G/GZ 179 §14A. Godement Criterion for compactness of H/HZ 179 §14B. Dirichlet’s Unit Theorem 179 §14C. Reduction theory: a weak fundamental domain for G/GZ 179 §14D. Large-scale geometry of Γ\X 180 §14E. References 180 Exercises 180 Chapter 15. Arithmetic Subgroups are Lattices 181 x Preliminary version (February 27, 2003) Contents §15A. G/GZ has finite volume 181 §15B. Divergent sequences in G/GZ 181 §15C. Proof of Godement’s Criterion 181 §15D. References 181 Exercises 181 Chapter 16. Zassenhaus Neighborhood 182 §16A. Zassenhaus neighborhood 182 §16B. Lower bound on vol(Γ\G) 182 §16C. Existence of maximal lattices 182 §16D. Noncocompact lattices have unipotent elements 182 §16E. Weak fundamental domain for G/Γ 182 §16F. References 182 Exercises 182 Chapter 17. Rigidity, Strong Rigidity and Superrigidity 183 §17A. Deformations of Γ 183 §17B. Representation Varieties 183 §17C. Mostow Rigidity Theorem 183 §17D. Proof of the Mostow Rigidity Theorem 184 §17E. Quasi-isometry rigidity 184 §17F. Margulis Superrigidity Theorem 185 §17G. Homomorphisms into compact groups 187 §17H. Geometric superrigidity 187 §17I. A nonarithmetic superrigid group 187 §17J. Notes 187 §17K. References 188 Chapter 18. Root Systems 189 §18A. Roots of complex Lie algebras 189 §18B. Definition of roots 189 §18C. Classification of semisimple Lie algebras over C 190 §18D. Dynkin diagrams 190 §18E. The root system BC 191 n §18F. Real roots 191 §18G. Q-roots 191 §18H. Notes 192 §18I. References 192 Exercises 192 Chapter 19. Basic Properties of Semisimple Algebraic k-Groups 193 §19A. Kneser-Tits Conjecture 193 §19B. BN-pairs 193