A geometric approach to alternating k-linear forms

Abstract

Given an n-dimensional vector space V over a field K, let 2≤ k < n. There is a natural correspondence between the alternating k-linear forms of V and the linear functionals f of kV. Let k: Gk(V)→ PG(kV) be the Plucker embedding of the k-Grassmannian Gk(V) of V. Then k-1((f)k(Gk(V))) is a hyperplane of the point-line geometry Gk(V). All hyperplanes of Gk(V) can be obtained in this way. For a hyperplane H of Gk(V), let R(H) be the subspace of Gk-1(V) formed by the (k-1)-subspaces A⊂ V such that H contains all k-subspaces that contain A. In other words, if is the (unique modulo a scalar) alternating k-linear form defining H, then the elements of R(H) are the (k-1)-subspaces A = a1,…, ak-1 of V such that (a1,…, ak-1,x) = 0 for all x∈ V. When n-k is even it might be that R(H) = . When n-k is odd, then R(H) ≠ , since every (k-2)-subspace of V is contained in at least one member of R(H). If every (k-2)-subspace of V is contained in precisely one member of R(H) we say that R(H) is spread-like. In this paper we obtain some results on R(H) which answer some open questions from the literature and suggest the conjecture that, if n-k is even and at least 4, then R(H) ≠ but for one exception with K≤ R and (n,k) = (7,3), while if n-k is odd and at least 5 then R(H) is never spread-like.