Layer potentials for elliptic operators with DMO-type coefficients: big pieces Tb theorem, quantitative rectifiability, and free boundary problems

Abstract

For n ≥ 2, we consider the operator LA = -div (A(·)∇), where A is a uniformly elliptic (n+1)×(n+1) matrix with variable coefficients, a Radon measure μ on Rn+1, and the associated gradient of the single layer potential operator Tμ. Under a Dini-type assumption on the mean oscillation of the matrix A, we establish the following results: 1) A rectifiability criterion for μ in terms of Tμ. Under quantitative geometric and analytic assumptions within a ball B -- including an upper n-growth condition on μ in B, a thin boundary condition, a scale-invariant decay condition expressed via a weighted sum of densities over dyadic dilations of B, and L2 boundedness of the gradient of Tμ -- we show the following: if the support of μ lies very close to an n-plane in B, and Tμ 1 is nearly constant on B in the L2 sense, then there exists a uniformly n-rectifiable set such that μ(B ) μ(B). 2) A Tb theorem for suppressed Tμ, which extends a well-known theorem of Nazarov, Treil, and Volberg, and holds also for a broader class of singular integral operators. These results make it possible to prove both qualitative and quantitative one- and two-phase free boundary problems for elliptic measure, formulated in terms of (uniform) rectifiability, in bounded Wiener-regular domains.