Local commutants and ultrainvariant subspaces

Abstract

For an operator A on a complex Banach space X and a closed subspace M⊂eq X, the local commutant of A at M is the set C(A;M) of all operators T on X such that TAx=ATx for every x∈ M. It is clear that C(A;M) is a closed linear space of operators, however it is not an algebra, in general. For a given A, we show that C(A;M) is an algebra if and only if the largest subspace MA such that C(A;M)=C(A;MA) is invariant for every operator in C(A;M). We say that these are ultrainvariant subspaces of A. For several types of operators we prove that there exist non-trivial ultrainvariant subspaces. For a normal operator on a Hilbert space, every hyperinvariant subspace is ultrainvariant. On the other hand, the lattice of all ultrainvariant subspaces of a non-zero nilpotent operator can be strictly smaller than the lattice of all hyperinvariant subspaces.