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El. knyga: Moments, Monodromy, and Perversity: A Diophantine Perspective

  • Formatas: 488 pages
  • Serija: Annals of Mathematics Studies
  • Išleidimo metai: 12-Sep-2005
  • Leidėjas: Princeton University Press
  • Kalba: eng
  • ISBN-13: 9781400826957
Kitos knygos pagal šią temą:
Moments, Monodromy, and Perversity: A Diophantine PerspectiveDidesnis paveikslėlis
  • Formatas: 488 pages
  • Serija: Annals of Mathematics Studies
  • Išleidimo metai: 12-Sep-2005
  • Leidėjas: Princeton University Press
  • Kalba: eng
  • ISBN-13: 9781400826957
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It is now some thirty years since Deligne first proved his general equidistribution theorem, thus establishing the fundamental result governing the statistical properties of suitably "pure" algebro-geometric families of character sums over finite fields (and of their associated L-functions). Roughly speaking, Deligne showed that any such family obeys a "generalized Sato-Tate law," and that figuring out which generalized Sato-Tate law applies to a given family amounts essentially to computing a certain complex semisimple (not necessarily connected) algebraic group, the "geometric monodromy group" attached to that family. Up to now, nearly all techniques for determining geometric monodromy groups have relied, at least in part, on local information. In Moments, Monodromy, and Perversity, Nicholas Katz develops new techniques, which are resolutely global in nature. They are based on two vital ingredients, neither of which existed at the time of Deligne's original work on the subject. The first is the theory of perverse sheaves, pioneered by Goresky and MacPherson in the topological setting and then brilliantly transposed to algebraic geometry by Beilinson, Bernstein, Deligne, and Gabber. The second is Larsen's Alternative, which very nearly characterizes classical groups by their fourth moments. These new techniques, which are of great interest in their own right, are first developed and then used to calculate the geometric monodromy groups attached to some quite specific universal families of (L-functions attached to) character sums over finite fields.
Introduction 1(8)
Basic results on perversity and higher moments
9(84)
The notion of a d-separating space of functions
9(3)
Review of semiperversity and perversity
12(1)
A twisting construction: the object Twist(L, K, F, h)
13(1)
The basic theorem and its consequences
13(8)
Review of weights
21(3)
Remarks on the various notions of mixedness
24(1)
The Orthogonality Theorem
25(6)
First Applications of the Orthogonality Theorem
31(5)
Questions of autoduality: the Frobenius-Schur indicator theorem
36(6)
Dividing out the ``constant part'' of an i-pure perverse sheaf
42(2)
The subsheaf Nncst0 in the mixed case
44(1)
Interlude: abstract trace functions; approximate trace functions
45(2)
Two uniqueness theorems
47(3)
The central normalization F0 of a trace function F
50(2)
First applications to the objects Twist(L, K, F, h): The notion of standard input
52(8)
Review of higher moments
60(1)
Higher moments for geometrically irreducible lisse sheaves
61(1)
Higher moments for geometrically irreducible perverse sheaves
62(1)
A fundamental inequality
62(2)
Higher moment estimates for Twist(L, K, F, h)
64(3)
Proof of the Higher Moment Theorem 1.20.2: combinatorial preliminaries
67(9)
Variations on the Higher Moment Theorem
76(11)
Counterexamples
87(6)
How to apply the results of
Chapter 1
93(18)
How to apply the Higher Moment Theorem
93(1)
Larsen's Alternative
94(2)
Larsen's Eighth Moment Conjecture
96(1)
Remarks on Larsen's Eighth Moment Conjecture
96(1)
How to apply Larsen's Eighth Moment Conjecture; its current status
97(1)
Other tools to rule out finiteness of Ggeom
98(4)
Some conjectures on drops
102(2)
More tools to rule out finiteness of Ggeom: sheaves of perverse origin and their monodromy
104(7)
Additive character sums on An
111(50)
The Lψ theorem
111(1)
Proof of the Lψ Theorem 3.1.2
112(1)
Interlude: the homothety contraction method
113(9)
Return to the proof of the Lψ theorem
122(1)
Monodromy of exponential sums of Deligne type on An
123(6)
Interlude: an exponential sum calculation
129(7)
Interlude: separation of variables
136(2)
Return to the monodromy of exponential sums of Deligne type on An
138(6)
Application to Deligne polynomials
144(2)
Self dual families of Deligne polynomials
146(3)
Proofs of the theorems on self dual families
149(7)
Proof of Theorem 3.10.7
156(2)
Proof of Theorem 3.10.9
158(3)
Additive character sums on more general X
161(24)
The general setting
161(5)
The perverse sheaf M(X, r, Zi's, ei's, ψ) on P(e1,...., er)
166(8)
Interlude An exponential sum identity
174(4)
Return to the proof of Theorem 4.2.12
178(1)
The subcases n = 1 and n = 2
179(6)
Multiplicative character sums on An
185(36)
The general setting
185(3)
First main theorem: the case when Xe is nontrivial
188(3)
Continuation of the proof of Theorem 5.2.2 for n = 1
191(9)
Continuation of the proof of Theorem 5.2.2 for general n
200(7)
Analysis of Gr0(M(n, e, x)), for e prime to p but Xe = 1
207(3)
Proof of Theorem 5.5.2 in the case n ≥ 2
210(11)
Middle additive convolution
221(74)
Middle convolution and its effect on local monodromy
221(12)
Interlude: some galois theory in one variable
233(7)
Proof of Theorem 6.2.11
240(5)
Interpretation in terms of Swan conductors
245(3)
Middle convolution and purity
248(5)
Application to the monodromy of multiplicative character sums in several variables
253(2)
Proof of Theorem 6.6.5, and applications
255(15)
Application to the monodromy of additive character sums in several variables
270(11)
Appendix A6: Swan-minimal poles
281(1)
Swan conductors of direct images
281(4)
An application to Swan conductors of pullbacks
285(2)
Interpretation in terms of canonical extensions
287(4)
Belyi polynomials, non-canonical extensions, and hypergeometric sheaves
291(4)
Pullbacks to curves from A1
295(26)
The general pullback setting
295(8)
General results on Ggeom for pullbacks
303(5)
Application to pullback families of elliptic curves and of their symmetric powers
308(4)
Cautionary examples
312(5)
Appendix: Degeneration of Leray spectral sequences
317(4)
One variable twists on curves
321(6)
Twist sheaves in the sense of [ Ka-TLFM]
321(3)
Monodromy of twist sheaves in the sense of [ Ka-TLFM]
324(3)
Weierstrass sheaves as inputs
327(22)
Weierstrass sheaves
327(3)
The situation when 2 is invertible
330(1)
Theorems of geometric irreducibility in odd characteristic
331(12)
Geometric Irreducibility in even characteristic
343(6)
Weierstrass families
349(22)
Universal Weierstrass families in arbitrary characteristic
349(7)
Usual Weierstrass families in characteristic p ≥ 5
356(15)
FJTwist families and variants
371(36)
(FJ, twist) families in characteristic p ≥ 5
371(9)
(j-1, twist) families in characteristic 3
380(10)
(j-1, twist) families in characteristic 2
390(11)
End of the proof of 11.3.25: Proof that Ggeom contains a reflection
401(6)
Uniformity results
407(36)
Fibrewise perversity: basic properties
407(2)
Uniformity results for monodromy; the basic setting
409(2)
The Uniformity Theorem
411(5)
Applications of the Uniformity Theorem to twist sheaves
416(5)
Applications to multiplicative character sums
421(6)
Non-application (sic!) to additive character sums
427(1)
Application to generalized Weierstrass families of elliptic curves
428(2)
Application to usual Weierstrass families of elliptic curves
430(3)
Application to FJTwist families of elliptic curves
433(2)
Applications to pullback families of elliptic curves
435(4)
Application to quadratic twist families of elliptic curves
439(4)
Average analytic rank and large N limits
443(12)
The basic setting
443(5)
Passage to the large N limit: general results
448(1)
Application to generalized Weierstrass families of elliptic curves
449(1)
Application to usual Weierstrass families of elliptic curves
450(1)
Applications to FJTwist families of elliptic curves
451(1)
Applications to pullback families of elliptic curves
452(1)
Applications to quadratic twist families of elliptic curves
453(2)
References 455(6)
Notation Index 461(6)
Subject Index 467


Nicholas M. Katz is Professor of Mathematics at Princeton University. He is the author of five previous books in this series: "Arithmetic Moduli of Elliptic Curves" (with Barry Mazur); "Gauss Sums, Kloosterman Sums, and Monodromy Groups"; "Exponential Sums and Differential Equations"; "Rigid Local Systems"; and "Twisted L-Functions and Monodromy".
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