The power operation in the Galois cohomology of a reductive group over a number field

Abstract

For a connected reductive group G over a local or global field K, we define a *diamond* (or *power*) operation (,n) n\,\, H1(K,G)× Z H1(K,G) of raising to power n in the Galois cohomology pointed set (this operation is new when K is a number field). We show that this power operation has many good properties. When G is a torus, the set H1(K,G) has a natural group structure, and n then coincides with the n-th power of in this group. On the other hand, we show that a power operation on H1(K,G), functorial in G, which we define over local and global fields, cannot be defined for an arbitrary field K. Our proof of this assertion relies on the results of Appendix B written by Philippe Gille. Using this power operation, for a cohomology class in H1(K,G) over local or global field, we define the period per() to be the least integer n 1 such that n=1. We define the index ind() to be the greatest common divisor of the degrees [L:K] of finite extensions L/K splitting . The period and index of a cohomology class generalize the period and index a central simple algebra over K. For any connected reductive group G defined over a local or global field K, we show that per() divides ind() and that ind() may be strictly greater than per(), but they always have the same prime factors.