Complex Multiplication - James Milne

1 Complex Multiplication Milne April 7, 2006. These are preliminary notes1 for a modern account of the theory of Complex multipli- cation. A shortened (minimal) version will be included in my book on Shimura varieties, and a complete longer version may one day be published separately. April 7, 2006. First version posted on the web; 113 pages. Please send comments and corrections to me at Available at c 2006. Milne . Copyright 1 This should be taken seriously: there are omissions, repetitions, clumsy statements and proofs, and incon- sistencies in notation.

2 Contents Contents 3. I Analytic theory 9. 1 CM-algebras and CM-types .. 9. Review of semisimple algebras and their modules 9; CM-algebras 11; CM-types. 12; The reflex field of a CM-pair 14; The reflex norm. 15; Classification of the primitive CM-pairs 19; Positive involutions and CM-algebras 21. 2 Complex abelian varieties .. 22. Complex tori 22; The cohomology of Complex tori 24; Hermitian forms and alternating forms 26; Riemann forms 26; Abelian varieties 28. 3 Abelian varieties with Complex Multiplication .. 29.

3 Definition of CM abelian varieties 29; The reflex field of an abelian variety with Complex Multiplication 31; Classification up to isogeny 31; Classification up to isomorphism 32. 4 Mumford-Tate groups .. 33. Review of algebraic groups of multiplicative type 33; CM-pairs and tori 35; The reflex norm in terms of tori 36; Complex Multiplication in terms of tori 36; Mumford-Tate groups 37; Infinity types 38; The Serre group 42; Abelian varieties of CM-type 46. 5 Motives .. 46. The Hodge structure of an abelian variety 46; Abelian motives 46; Hodge structures 46.

4 CM-motives 46. II The arithmetic theory 49. 6 Abelian varieties and their good reductions .. 49. Complex abelian varieties and Complex tori 49; Specialization of abelian varieties 51; The good reduction of abelian varieties 51. 7 Abelian varieties with Complex Multiplication .. 55. Definition of a CM abelian variety 55; Complex Multiplication by a Q-algebra 55; Specialization 57; Rigidity 57; Good reduction 58; The degrees of isogenies 58; a-multiplications (1) 60;. a-multiplications (2) 64; a-multiplications (3) 66.

5 8 The Shimura-Taniyama formula .. 68. Review of numerical norms 68; Statement and proof 68; Alternative approach using schemes (Giraud 1968) 72; Alternative approach using p-divisible groups (Tate 1968). 73; Alternative approach using crystals (Deligne c1968) 74; Alternative approach using Hodge-Tate decompositions (Serre 1968) 75. 9 The fundamental theorem over the reflex field .. 76. Review of the reflex norm 76; Preliminaries from algebraic number theory 76; The funda- mental theorem in terms of ideals 77; More preliminaries from algebraic number theory 3.

6 4 CONTENTS. 78; The fundamental theorem in terms of id`eles 79; The fundamental theorem in terms of uniformizations 82; The fundamental theorem in terms of moduli 83; Alternative ap- proach using crystals (Deligne c1968) 85. 10 The fundamental theorem of Complex Multiplication .. 90. Statement of the Theorem 90; Definition of f . / 92; Proof of Theorem up to an element of order 2 95; Completion of the proof (following Deligne) 97. III CM-motives 99. IV Applications 101. A Additional notes; solutions to the exercises 103.

7 B Summary 105. Bibliography 109. Index of definitions 112. Preface The theory of Complex Multiplication is not only the most beautiful part of mathematics but also of all science. D. Hilbert2. Abelian varieties with Complex multiplication3 are special in that they have the largest possible endomorphism rings. For example, the endomorphism ring of an elliptic curve is usually Z, but when it is not, it is an order in an imaginary quadratic number field, and the elliptic curve is then said to have Complex Multiplication .

8 Similarly, the endomorphism ring of a simple abelian variety of dimension g is usually Z, but, at the opposite extreme, it may be an order in a number field of degree 2g, in which case the abelian variety is said to have Complex Multiplication . Abelian varieties with Complex Multiplication correspond to special points on the moduli variety of abelian varieties, and their arithmetic is intimately related to that of the values of modular functions and modular forms at those points. The first important result in the subject, which goes back to Kronecker and Weber, states that the Hilbert class field (maximal abelian unramified extension) of an imaginary quadratic subfield E of C is generated by the special value j.

9 / of the j -function at any element of E in the Complex upper half plane generating the ring of integers in E. Here j is the holomorphic function on the Complex upper half plane invariant under the action 1C. p 3. p of SL2 .Z/, taking the values 0 and 1728 respectively at 2 and 1, and having a simple pole at infinity. The statement is related to elliptic curves through the ideal class group of E, which acts naturally both on the Hilbert class field of E and on the set of isomorphism classes of elliptic curves with endomorphism ring OE.

10 Generalizing this, Hilbert asked in the twelfth of his famous problems whether there ex- ist holomorphic functions whose special values generate the abelian extensions (in particu- lar, the class fields) of arbitrary number fields. For quadratic imaginary fields, the theory of elliptic curves with Complex Multiplication shows that elliptic modular functions have this property (Kronecker, Weber, Takagi, Hasse). Hecke began the study of abelian surfaces 2 As quoted by Olga Taussky in her obituary for Hilbert in Nature, 152 (1943), 182 183.