Semilinear spaces of matrices with transitivity, rank or spectral constraints

Abstract: Let $\mathbb{D}$ be a division ring with finite degree over a central subfield $\mathbb{F}$. Under mild cardinality assumptions on $\mathbb{F}$, we determine the greatest possible dimension for an $\mathbb{F}$-linear subspace of $M_n(\mathbb{D})$ in which no matrix has a nonzero fixed vector, and we elucidate the structure of the spaces that have the greatest dimension. The classification involves the associative composition algebras over $\mathbb{F}$ and requires the study of intransitive spaces of operators between finite-dimensional vector spaces. These results are applied to solve various problems of the same flavor, including the determination of the greatest possible dimension for an $\mathbb{F}$-affine subspace of $M_{n,p}(\mathbb{D})$ in which all the matrices have rank at least $r$ (for some fixed $r$), as well as the structure of the spaces that have the greatest possible dimension if $n=p=r$; and finally the structure of large $\mathbb{F}$-linear subspaces of $\mathbb{F}$-diagonalisable matrices is elucidated.