Perturbation Theory for Second Order Elliptic Operators with BMO Antisymmetric Part

Abstract

AbstractIn the present paper we study perturbation theory for the $$L^p$$ L p Dirichlet problem on bounded chord arc domains for elliptic operators in divergence form with potentially unbounded antisymmetric part in BMO. Specifically, given elliptic operators $$L_0 = \text {div}(A_0\nabla )$$ L 0 = div ( A 0 ∇ ) and $$L_1 = \text {div}(A_1\nabla )$$ L 1 = div ( A 1 ∇ ) such that the $$L^p$$ L p Dirichlet problem for $$L_0$$ L 0 is solvable for some $$p>1$$ p > 1 ; we show that if $$A_0 - A_1$$ A 0 - A 1 satisfies certain Carleson condition, then the $$L^q$$ L q Dirichlet problem for $$L_1$$ L 1 is solvable for some $$q \ge p$$ q ≥ p . Moreover if the Carleson norm is small then we may take $$q=p$$ q = p . We use the approach first introduced in Fefferman–Kenig–Pipher ’91 on the unit ball, and build on Milakis–Pipher–Toro ’11 where the large norm case was shown for symmetric matrices on bounded chord arc domains. We then apply this to solve the $$L^p$$ L p Dirichlet problem on a bounded Lipschitz domain for an operator $$L = \text {div}(A\nabla )$$ L = div ( A ∇ ) , where A satisfies a Carleson condition similar to the one assumed in Kenig–Pipher ’01 and Dindoš–Petermichl–Pipher ’07 but with unbounded antisymmetric part.