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Tate–Shafarevich group

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In arithmetic geometry, the Tate–Shafarevich group Ш(A/K) of an abelian variety A (or more generally a group scheme) defined over a number field K consists of the elements of the Weil–Châtelet group , where is the absolute Galois group of K, that become trivial in all of the completions of K (i.e., the real and complex completions as well as the p-adic fields obtained from K by completing with respect to all its Archimedean and non Archimedean valuations v). Thus, in terms of Galois cohomology, Ш(A/K) can be defined as

This group was introduced by Serge Lang and John Tate[1] and Igor Shafarevich.[2] Cassels introduced the notation Ш(A/K), where Ш is the Cyrillic letter "Sha", for Shafarevich, replacing the older notation TS or .

Elements of the Tate–Shafarevich group

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Geometrically, the non-trivial elements of the Tate–Shafarevich group can be thought of as the homogeneous spaces of A that have Kv-rational points for every place v of K, but no K-rational point. Thus, the group measures the extent to which the Hasse principle fails to hold for rational equations with coefficients in the field K. Carl-Erik Lind gave an example of such a homogeneous space, by showing that the genus 1 curve x4 − 17 = 2y2 has solutions over the reals and over all p-adic fields, but has no rational points.[3] Ernst S. Selmer gave many more examples, such as 3x3 + 4y3 + 5z3 = 0.[4]

The special case of the Tate–Shafarevich group for the finite group scheme consisting of points of some given finite order n of an abelian variety is closely related to the Selmer group.

Tate-Shafarevich conjecture

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The Tate–Shafarevich conjecture states that the Tate–Shafarevich group is finite. Karl Rubin proved this for some elliptic curves of rank at most 1 with complex multiplication.[5] Victor A. Kolyvagin extended this to modular elliptic curves over the rationals of analytic rank at most 1 (The modularity theorem later showed that the modularity assumption always holds).[6] Theorem 1.1 of Nikolaev [7] treats simple abelian varieties over number fields.

It is known that the Tate–Shafarevich group is a torsion group,[8][9] thus the conjecture is equivalent to stating that the group is finitely generated.

Cassels–Tate pairing

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The Cassels–Tate pairing is a bilinear pairing Ш(A) × Ш(Â) → Q/Z, where A is an abelian variety and  is its dual. Cassels introduced this for elliptic curves, when A can be identified with  and the pairing is an alternating form.[10] The kernel of this form is the subgroup of divisible elements, which is trivial if the Tate–Shafarevich conjecture is true. Tate extended the pairing to general abelian varieties, as a variation of Tate duality.[11] A choice of polarization on A gives a map from A to Â, which induces a bilinear pairing on Ш(A) with values in Q/Z, but unlike the case of elliptic curves this need not be alternating or even skew symmetric.

For an elliptic curve, Cassels showed that the pairing is alternating, and a consequence is that if the order of Ш is finite then it is a square. For more general abelian varieties it was sometimes incorrectly believed for many years that the order of Ш is a square whenever it is finite; this mistake originated in a paper by Swinnerton-Dyer,[12] who misquoted one of the results of Tate.[11] Poonen and Stoll gave some examples where the order is twice a square, such as the Jacobian of a certain genus 2 curve over the rationals whose Tate–Shafarevich group has order 2,[13] and Stein gave some examples where the power of an odd prime dividing the order is odd.[14] If the abelian variety has a principal polarization then the form on Ш is skew symmetric which implies that the order of Ш is a square or twice a square (if it is finite), and if in addition the principal polarization comes from a rational divisor (as is the case for elliptic curves) then the form is alternating and the order of Ш is a square (if it is finite). On the other hand building on the results just presented Konstantinou showed that for any squarefree number n there is an abelian variety A defined over Q and an integer m with |Ш| = n ⋅ m2.[15] In particular Ш is finite in Konstantinou's examples and these examples confirm a conjecture of Stein. Thus modulo squares any integer can be the order of Ш.

See also

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Citations

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  1. ^ Lang & Tate 1958.
  2. ^ Shafarevich 1959.
  3. ^ Lind 1940.
  4. ^ Selmer 1951.
  5. ^ Rubin 1987.
  6. ^ Kolyvagin 1988.
  7. ^ Nikolaev, Igor V. (2024), Shafarevich-Tate groups of abelian varieties, Contemporary Mathematics, vol. 798, American Mathematical Society, pp. 229–239, arXiv:2005.09970, doi:10.1090/conm/798/15988
  8. ^ Kolyvagin, V. A. (1991), "On the structure of shafarevich-tate groups", Algebraic Geometry, Lecture Notes in Mathematics, vol. 1479, Springer Berlin Heidelberg, pp. 94–121, doi:10.1007/bfb0086267, ISBN 978-3-540-54456-2
  9. ^ Poonen, Bjorn (2024-09-01). "THE SELMER GROUP, THE SHAFAREVICH-TATE GROUP, AND THE WEAK MORDELL-WEIL THEOREM" (PDF).
  10. ^ Cassels 1962.
  11. ^ a b Tate 1963.
  12. ^ Swinnerton-Dyer 1967.
  13. ^ Poonen & Stoll 1999.
  14. ^ Stein 2004.
  15. ^ Konstantinou 2024.

References

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