Extensions of isomorphisms for affine Grassmannians over F2

In Blok [1] affinely rigid classes of geometries were studied. These are classes B of geometries with the following property: Given any two geometries Gamma(1), Gamma(2) is an element of B with subspaces L-1 and L-2 respectively, then any isomorphism Gamma(1)-L1 ->Gamma(2)-L-2 uniquely extends to an isomorphism Gamma(1)->Gamma(2). Suppose Gamma belongs to an affinely rigid class. Then for any subspace L we have Aut(Gamma-L)<= Aut(Gamma). Suppose that, in addition, Gamma is embedded into the projective space P(V) for some vector space V. Then one may think of V as a "natural" embedding if every automorphism of Gamma is induced by some (semi-) linear automorphism of V. This is for instance true of the projective geometry Gamma=P(V) itself by the fundamental theorem of projective geometry. Clearly since Gamma belongs to an affinely rigid class and has a natural embedding into P(V), also the embedding Gamma-L into P(V) is natural. In Blok [1] the notion of a layer-extendable class was introduced and it was shown that layer-extendable classes are affinely rigid. As an application, it was shown that the union of most projective geometries, (dual) polar spaces, and strong parapolar spaces forms an affinely rigid class. However, the geometries motivating that study, the Grassmannians defined over F-2, were not included in this class because they do not form a layer-extendable class. Since affine projective geometries (1-Grassmannians, if you will) are simply complete graphs, clearly they are not affinely rigid at all. In the present note we show that also the class of 2-Grassmannians over F-2 fails to form an affinely rigid class, although in a less dramatic way, whereas the class of k-Grassmannians of projective spaces of dimension n over F-2 where 3 <= k <= n-2 is in fact affinely rigid.