Avner Ash is Professor in the Department of Mathematics at Boston College, Massachusetts.

Preface xiii Acknowledgments xix Prologue 1 PART I. DEGREE Chapter 1. Degree of a Curve 13 1. Greek Mathematics 13 2. Degree 14 3. Parametric Equations 20 4. Our Two Definitions of Degree Clash 23 Chapter 2. Algebraic Closures 26 1. Square Roots of Minus One 26 2. Complex Arithmetic 28 3. Rings and Fields 30 4. Complex Numbers and Solving Equations 32 5. Congruences 34 6. Arithmetic Modulo a Prime 38 7. Algebraic Closure 38 Chapter 3. The Projective Plane 42 1. Points at Infinity 42 2. Projective Coordinates on a Line 46 3. Projective Coordinates on a Plane 50 4. Algebraic Curves and Points at Infinity 54 5. Homogenization of Projective Curves 56 6. Coordinate Patches 61 Chapter 4. Multiplicities and Degree 67 1. Curves as Varieties 67 2. Multiplicities 69 3. Intersection Multiplicities 72 4. Calculus for Dummies 76 Chapter 5. B'ezout's Theorem 82 1. A Sketch of the Proof 82 2. An Illuminating Example 88 PART II. ELLIPTIC CURVES AND ALGEBRA Chapter 6. Transition to Elliptic Curves 95 Chapter 7. Abelian Groups 100 1. How Big Is Infinity? 100 2. What Is an Abelian Group? 101 3. Generations 103 4. Torsion 106 5. Pulling Rank 108 Appendix: An Interesting Example of Rank and Torsion 110 Chapter 8. Nonsingular Cubic Equations 116 1. The Group Law 116 2. Transformations 119 3. The Discriminant 121 4. Algebraic Details of the Group Law 122 5. Numerical Examples 125 6. Topology 127 7. Other Important Facts about Elliptic Curves 131 5. Two Numerical Examples 133 Chapter 9. Singular Cubics 135 1. The Singular Point and the Group Law 135 2. The Coordinates of the Singular Point 136 3. Additive Reduction 137 4. Split Multiplicative Reduction 139 5. Nonsplit Multiplicative Reduction 141 6. Counting Points 145 7. Conclusion 146 Appendix A: Changing the Coordinates of the Singular Point 146 Appendix B: Additive Reduction in Detail 147 Appendix C: Split Multiplicative Reduction in Detail 149 Appendix D: Nonsplit Multiplicative Reduction in Detail 150 Chapter 10. Elliptic Curves over Q 152 1. The Basic Structure of the Group 152 2. Torsion Points 153 3. Points of Infinite Order 155 4. Examples 156 PART III. ELLIPTIC CURVES AND ANALYSIS Chapter 11. Building Functions 161 1. Generating Functions 161 2. Dirichlet Series 167 3. The Riemann Zeta-Function 169 4. Functional Equations 171 5. Euler Products 174 6. Build Your Own Zeta-Function 176 Chapter 12. Analytic Continuation 181 1. A Difference that Makes a Difference 181 2. Taylor Made 185 3. Analytic Functions 187 4. Analytic Continuation 192 5. Zeroes, Poles, and the Leading Coefficient 196 Chapter 13. L-functions 199 1. A Fertile Idea 199 2. The Hasse-Weil Zeta-Function 200 3. The L-Function of a Curve 205 4. The L-Function of an Elliptic Curve 207 5. Other L-Functions 212 Chapter 14. Surprising Properties of L-functions 215 1. Compare and Contrast 215 2. Analytic Continuation 220 3. Functional Equation 221 Chapter 15. The Conjecture of Birch and Swinnerton-Dyer 225 1. How Big Is Big? 225 2. Influences of the Rank on the Np's 228 3. How Small Is Zero? 232 4. The BSD Conjecture 236 5. Computational Evidence for BSD 238 6. The Congruent Number Problem 240 Epilogue 245 Retrospect 245 Where DoWe Go from Here? 247 Bibliography 249 Index 251

Elliptic Tales describes the latest developments in number theory by looking at one of the most exciting unsolved problems in contemporary mathematics--the Birch and Swinnerton-Dyer Conjecture. In this book, Avner Ash and Robert Gross guide readers through the mathematics they need to understand this captivating problem.