Preserving of the unconditional basis property under non-self-adjoint perturbations of self-adjoint operators

Abstract

Let T be a self-adjoint operator in a Hilbert space H with domain D(T). Assume that the spectrum of T is confined in the union of disjoint intervals k =[α2k-1,α2k], k∈ Z, and α2k+1-α2k ≥ b|α2k+1+α2k|p for some \,b>0,\,p∈[0,1). Suppose that a linear operator B in H is p-subordinated to T, i.e. D(B) ⊃ D(T) and \|Bx\| ≤ b'\,\|Tx\|p\|x\|1-p +M\|x\| \, for all x∈ D(T), with some b'>0 and M≥ 0. Then the spectrum of the perturbed operator A=T+B lies in the union of a rectangle in C and double parabola Pp,h = \λ ∈ C\,|\,| Im λ|≤ h| Re λ|p\, provided that h>b'. The vertical strips k =\λ∈C|\,|rk- Re\,λ|≤ δ rkp\, rk =(α2k+α2k+1)/2, belong to the resolvent set of T, provided that δ <b -b' and |k|≥ N for N large enough. For |k| N+1, denote by k the curvilinear trapezoid formed by the lines Re\,λ = rk-1, Re\,λ = rk, and the boundary of the parabola Pp,h. Assume that Q0 is the Riesz projection corresponding to the (bounded) part of the spectrum of T that lies outside |k|≥ N+1k. And let Qk, |k| N+1, be the Riesz projection for the part of the spectrum of T confined within k. Main result of the work consists in proving that the system of the invariant subspaces Qk(H), |k|≥ N+1, together with the invariant subspace Q0(H) forms an unconditional basis of subspaces in the space H.