| Foreword | p. xv |
| Preface to the Paperback Edition | p. xxi |
| Preface | p. xxv |
| Acknowledgments | p. xxxi |
| Greek Alphabet | p. xxxiii |
| Algebraic Preliminaries | |
| Representations | p. 3 |
| The Bare Notion of Representation | p. 3 |
| An Example: Counting | p. 5 |
| Digression: Definitions | p. 6 |
| Counting (Continued) | p. 7 |
| Counting Viewed as a Representation | p. 8 |
| The Definition of a Representation | p. 9 |
| Counting and Inequalities as Representations | p. 10 |
| Summary | p. 11 |
| Groups | p. 13 |
| The Group of Rotations of a Sphere | p. 14 |
| The General Concept of "Group" | p. 17 |
| In Praise of Mathematical Idealization | p. 18 |
| Digression: Lie Groups | p. 19 |
| Permutations | p. 21 |
| The abc of Permutations | p. 21 |
| Permutations in General | p. 25 |
| Cycles | p. 26 |
| Digression: Mathematics and Society | p. 29 |
| Modular Arithmetic | p. 31 |
| Cyclical Time | p. 31 |
| Congruences | p. 33 |
| Arithmetic Modulo a Prime | p. 36 |
| Modular Arithmetic and Group Theory | p. 39 |
| Modular Arithmetic and Solutions of Equations | p. 41 |
| Complex Numbers | p. 42 |
| Overture to Complex Numbers | p. 42 |
| Complex Arithmetic | p. 44 |
| Complex Numbers and Solving Equations | p. 47 |
| Digression: Theorem | p. 47 |
| Algebraic Closure | p. 47 |
| Equations and Varieties | p. 49 |
| The Logic of Equality | p. 50 |
| The History of Equations | p. 50 |
| Z-Equations | p. 52 |
| Varieties | p. 54 |
| Systems of Equations | p. 56 |
| Equivalent Descriptions of the Same Variety | p. 58 |
| Finding Roots of Polynomials | p. 61 |
| Are There General Methods for Finding Solutions to Systems of Polynomial Equations? | p. 62 |
| Deeper Understanding Is Desirable | p. 65 |
| Quadratic Reciprocity | p. 67 |
| The Simplest Polynomial Equations | p. 67 |
| When is -1 a Square mod p? | p. 69 |
| The Legendre Symbol | p. 71 |
| Digression: Notation Guides Thinking | p. 72 |
| Multiplicativity of the Legendre Symbol | p. 73 |
| When Is 2 a Square mod p? | p. 74 |
| When Is 3 a Square mod p? | p. 75 |
| When Is 5 a Square mod p? (Will This Go On Forever?) | p. 76 |
| The Law of Quadratic Reciprocity | p. 78 |
| Examples of Quadratic Reciprocity | p. 80 |
| Galois Theory and Representations | |
| Galois Theory | p. 87 |
| Polynomials and Their Roots | p. 88 |
| The Field of Algebraic Numbers Q[superscript alg] | p. 89 |
| The Absolute Galois Group of Q Defined | p. 92 |
| A Conversation with s: A Playlet in Three Short Scenes | p. 93 |
| Digression: Symmetry | p. 96 |
| How Elements of G Behave | p. 96 |
| Why Is G a Group? | p. 101 |
| Summary | p. 101 |
| Elliptic Curves | p. 103 |
| Elliptic Curves Are "Group Varieties" | p. 103 |
| An Example | p. 104 |
| The Group Law on an Elliptic Curve | p. 107 |
| A Much-Needed Example | p. 108 |
| Digression: What Is So Great about Elliptic Curves? | p. 109 |
| The Congruent Number Problem | p. 110 |
| Torsion and the Galois Group | p. 111 |
| Matrices | p. 114 |
| Matrices and Matrix Representations | p. 114 |
| Matrices and Their Entries | p. 115 |
| Matrix Multiplication | p. 117 |
| Linear Algebra | p. 120 |
| Digression: Graeco-Latin Squares | p. 122 |
| Groups of Matrices | p. 124 |
| Square Matrices | p. 124 |
| Matrix Inverses | p. 126 |
| The General Linear Group of Invertible Matrices | p. 129 |
| The Group GL(2, Z) | p. 130 |
| Solving Matrix Equations | p. 132 |
| Group Representations | p. 135 |
| Morphisms of Groups | p. 135 |
| A[subscript 4], Symmetries of a Tetrahedron | p. 139 |
| Representations of A[subscript 4] | p. 142 |
| Mod p Linear Representations of the Absolute Galois Group from Elliptic Curves | p. 146 |
| The Galois Group of a Polynomial | p. 149 |
| The Field Generated by a Z-Polynomial | p. 149 |
| Examples | p. 151 |
| Digression: The Inverse Galois Problem | p. 154 |
| Two More Things | p. 155 |
| The Restriction Morphism | p. 157 |
| The Big Picture and the Little Pictures | p. 157 |
| Basic Facts about the Restriction Morphism | p. 159 |
| Examples | p. 161 |
| The Greeks Had a Name for It | p. 162 |
| Traces | p. 163 |
| Conjugacy Classes | p. 165 |
| Examples of Characters | p. 166 |
| How the Character of a Representation Determines the Representation | p. 171 |
| Prelude to the Next Chapter | p. 175 |
| Digression: A Fact about Rotations of the Sphere | p. 175 |
| Frobenius | p. 177 |
| Something for Nothing | p. 177 |
| Good Prime, Bad Prime | p. 179 |
| Algebraic Integers, Discriminants, and Norms | p. 180 |
| A Working Definition of Frob[subscript p] | p. 184 |
| An Example of Computing Frobenius Elements | p. 185 |
| Frob[subscript p] and Factoring Polynomials modulo p | p. 186 |
| The Official Definition of the Bad Primes for a Galois Representation | p. 188 |
| The Official Definition of "Unramified" and Frob[subscript p] | p. 189 |
| Reciprocity Laws | |
| Reciprocity Laws | p. 193 |
| The List of Traces of Frobenius | p. 193 |
| Black Boxes | p. 195 |
| Weak and Strong Reciprocity Laws | p. 196 |
| Digression: Conjecture | p. 197 |
| Kinds of Black Boxes | p. 199 |
| One- and Two-Dimensional Representations | p. 200 |
| Roots of Unity | p. 200 |
| How Frob[subscript q] Acts on Roots of Unity | p. 202 |
| One-Dimensional Galois Representations | p. 204 |
| Two-Dimensional Galois Representations Arising from the p-Torsion Points of an Elliptic Curve | p. 205 |
| How Frob[subscript q] Acts on p-Torsion Points | p. 207 |
| The 2-Torsion | p. 209 |
| An Example | p. 209 |
| Another Example | p. 211 |
| Yet Another Example | p. 212 |
| The Proof | p. 214 |
| Quadratic Reciprocity Revisited | p. 216 |
| Simultaneous Eigenelements | p. 217 |
| The Z-Variety x[superscript 2] - W | p. 218 |
| A Weak Reciprocity Law | p. 220 |
| A Strong Reciprocity Law | p. 221 |
| A Derivation of Quadratic Reciprocity | p. 222 |
| A Machine for Making Galois Representations | p. 225 |
| Vector Spaces and Linear Actions of Groups | p. 225 |
| Linearization | p. 228 |
| Etale Cohomology | p. 229 |
| Conjectures about Etale Cohomology | p. 231 |
| A Last Look at Reciprocity | p. 233 |
| What Is Mathematics? | p. 233 |
| Reciprocity | p. 235 |
| Modular Forms | p. 236 |
| Review of Reciprocity Laws | p. 239 |
| A Physical Analogy | p. 240 |
| Fermat's Last Theorem and Generalized Fermat Equations | p. 242 |
| The Three Pieces of the Proof | p. 243 |
| Frey Curves | p. 244 |
| The Modularity Conjecture | p. 245 |
| Lowering the Level | p. 247 |
| Proof of FLT Given the Truth of the Modularity Conjecture for Certain Elliptic Curves | p. 249 |
| Bring on the Reciprocity Laws | p. 250 |
| What Wiles and Taylor-Wiles Did | p. 252 |
| Generalized Fermat Equations | p. 254 |
| What Henri Darmon and Loic Merel Did | p. 255 |
| Prospects for Solving the Generalized Fermat Equations | p. 256 |
| Retrospect | p. 257 |
| Topics Covered | p. 257 |
| Back to Solving Equations | p. 258 |
| Digression: Why Do Math? | p. 260 |
| The Congruent Number Problem | p. 261 |
| Peering Past the Frontier | p. 263 |
| Bibliography | p. 265 |
| Index | p. 269 |
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