Symmetric bilinear Forms and Galois Theory

Abstract

Let K be a field admitting a Galois extension L of degree n, denoting the Galois group as G = (L/K). Our focus lies on the space K(L) of symmetric K-bilinear forms on L. We establish a decomposition of K(L) into direct sum of K-subspaces Aσi, where σi ∈ G. Notably, these subspaces Aσi exhibit nice constant rank properties. The central contribution of this paper is a decomposition theorem for K(L), revealing a direct sum of (n+1)2 constant rank n-subspaces, each having dimension of n. This holds particularly when G is cyclic, represented as G = (L/K) = σ. For cyclic extensions of even degree n = 2m, we present slightly less precise but analogous results. In this scenario, we enhance and enrich these constant results and show that, the component Aσ often decomposes directly into a constant rank subspaces. Remarkably, this decomposition is universally valid when -1 L2. Consequently, we derive a decomposition of K(L) into subspaces of constant rank under several situations. Moreover, leveraging these decompositions, we investigate the maximum dimension of an n-subspace inside M(n,K) and S(n,K) for various field K where M(n,K) and S(n,K) denote the vector spaces (n × n) matrices and symmetric matrices over K, respectively.