Cayley algebras give rise to q-Fano planes over certain infinite fields and q-covering designs over others

Abstract

Let F be a field. A 2-(7, 3, 1)F-subspace design, or q-Fano plane, over F, is a 7-dimensional vector space V over F together with a collection B of three-dimensional subspaces of V such that every two-dimensional subspace of V is contained in exactly one element B of B. The question of existence of q-Fano planes over any field has been open since the 1970s and has attracted considerable attention in the special case that F is finite. Here we show the existence of 2-(7, 3, 1)F-subspace designs over certain infinite fields F, including (among others) Q, R and Fq(x, y, z) for q odd. The space V is the 7-dimensional space of imaginary elements in a Cayley division algebra O over F and B consists of the intersections with V of all 4-dimensional subalgebras of O. We will present the required background on Cayley algebras in a self-contained fashion. Next we study what happens if we apply the same procedure to split (rather than division) Cayley algebras. By identifying all four-dimensional subalgebras of these, we show that in that case our construction still yields an inclusion minimal (7, 3, 2) q-covering design. That is: every two-dimensional subspace of V is contained in at least one element of the resulting set B of three-dimensional subspaces of V and no proper subset of B has this property. However none of these q-covering designs are q-Fano planes. In the case that F is finite we compute the number of elements of B. We also give a purely combinatorial construction of our q-Fano planes and q-covering designs for an abstract 7-dimensional F-vector space V by identifying the collection B as a subvariety of the Grassmanian Gr3(V) defined entirely in terms of the classical Fano plane.