Local Tate duality

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Short description: Duality for Galois modules for the absolute Galois group of a non-archimedean local field

In Galois cohomology, local Tate duality (or simply local duality) is a duality for Galois modules for the absolute Galois group of a non-archimedean local field. It is named after John Tate who first proved it. It shows that the dual of such a Galois module is the Tate twist of usual linear dual. This new dual is called the (local) Tate dual.

Local duality combined with Tate's local Euler characteristic formula provide a versatile set of tools for computing the Galois cohomology of local fields.

Statement

Let K be a non-archimedean local field, let Ks denote a separable closure of K, and let GK = Gal(Ks/K) be the absolute Galois group of K.

Case of finite modules

Denote by μ the Galois module of all roots of unity in Ks. Given a finite GK-module A of order prime to the characteristic of K, the Tate dual of A is defined as

[math]\displaystyle{ A^\prime=\mathrm{Hom}(A,\mu) }[/math]

(i.e. it is the Tate twist of the usual dual A). Let Hi(KA) denote the group cohomology of GK with coefficients in A. The theorem states that the pairing

[math]\displaystyle{ H^i(K,A)\times H^{2-i}(K,A^\prime)\rightarrow H^2(K,\mu)=\mathbf{Q}/\mathbf{Z} }[/math]

given by the cup product sets up a duality between Hi(K, A) and H2−i(KA) for i = 0, 1, 2.[1] Since GK has cohomological dimension equal to two, the higher cohomology groups vanish.[2]

Case of p-adic representations

Let p be a prime number. Let Qp(1) denote the p-adic cyclotomic character of GK (i.e. the Tate module of μ). A p-adic representation of GK is a continuous representation

[math]\displaystyle{ \rho:G_K\rightarrow\mathrm{GL}(V) }[/math]

where V is a finite-dimensional vector space over the p-adic numbers Qp and GL(V) denotes the group of invertible linear maps from V to itself.[3] The Tate dual of V is defined as

[math]\displaystyle{ V^\prime=\mathrm{Hom}(V,\mathbf{Q}_p(1)) }[/math]

(i.e. it is the Tate twist of the usual dual V = Hom(V, Qp)). In this case, Hi(K, V) denotes the continuous group cohomology of GK with coefficients in V. Local Tate duality applied to V says that the cup product induces a pairing

[math]\displaystyle{ H^i(K,V)\times H^{2-i}(K,V^\prime)\rightarrow H^2(K,\mathbf{Q}_p(1))=\mathbf{Q}_p }[/math]

which is a duality between Hi(KV) and H2−i(KV ′) for i = 0, 1, 2.[4] Again, the higher cohomology groups vanish.

See also

Notes

  1. Serre 2002, Theorem II.5.2
  2. Serre 2002, §II.4.3
  3. Some authors use the term p-adic representation to refer to more general Galois modules.
  4. Rubin 2000, Theorem 1.4.1

References

  • Rubin, Karl (2000), Euler systems, Hermann Weyl Lectures, Annals of Mathematics Studies, 147, Princeton University Press, ISBN 978-0-691-05076-8 
  • Serre, Jean-Pierre (2002), Galois cohomology, Springer Monographs in Mathematics, Berlin, New York: Springer-Verlag, ISBN 978-3-540-42192-4 , translation of Cohomologie Galoisienne, Springer-Verlag Lecture Notes 5 (1964).