Quantitative unique continuation for real-valued solutions to second order elliptic equations in the plane
Abstract
In this article, we study a quantitative form of the Landis conjecture on exponential decay for real-valued solutions to second order elliptic equations with variable coefficients in the plane. In particular, we prove the following qualitative form of Landis conjecture, for W1, W2 ∈ L∞( R2; R2), V ∈ L∞( R2; R) and u ∈ Hloc1( R2) a real-valued weak solution to - u - ∇ · ( W1 u ) +W2 · ∇ u + V u = 0 in R2, satisfying for δ>0, |u(x)| ≤ (- |x|1+δ), x ∈ R2, then u 0. Our methodology of proof is inspired by the one recently developed by Logunov, Malinnikova, Nadirashvili, and Nazarov that have treated the equation - u + V u = 0 in R2. Nevertheless, several differences and additional difficulties appear. New weak quantitative maximum principles are established for the construction of a positive multiplier in a suitable perforated domain, depending on the nodal set of u. The resulted divergence elliptic equation is then transformed into a non-homogeneous ∂z equation thanks to a generalization of Stoilow factorization theorem obtained by the theory of quasiconformal mappings, an approximate type Poincar\'e lemma and the use of the Cauchy transform. Finally, a suitable Carleman estimate applied to the operator ∂z is the last ingredient of our proof.
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