On Stability of Square Root Domains for Non-Self-Adjoint Operators Under Additive Perturbations

Abstract

Assuming T0 to be an m-accretive operator in the complex Hilbert space H, we use a resolvent method due to Kato to appropriately define the additive perturbation T = T0 + W and prove stability of square root domains, that is, dom((T0 + W)1/2) = dom(T01/2). Moreover, assuming in addition that dom(T01/2) = dom((T0*)1/2), we prove stability of square root domains in the form dom((T0 + W)1/2) = dom(T01/2) = dom((T0*)1/2) = dom(((T0 + W)*)1/2), which is most suitable for PDE applications. We apply this approach to elliptic second-order partial differential operators of the form - div(a∇ \, · \,) + (B1· ∇ · ) + div (B2 · ) + V in L2() on certain open sets ⊂eq Rn, n ∈ N, with Dirichlet, Neumann, and mixed boundary conditions on ∂ , under general hypotheses on the (typically, nonsmooth, unbounded) coefficients and on ∂.