A minimum problem associated with scalar Ginzburg-Landau equation and free boundary

Abstract

Let N>2, p∈ (2NN+2,+∞), and be an open bounded domain in RN. We consider the minimum problem J (u) := ∫ (1p| ∇ u| p+λ1(1-(u+)2)2+λ2u+)dx→ min over a certain class K, where λ1≥ 0 and λ2∈ R are constants, and u+:=\u,0\. The corresponding Euler-Lagrange equation is related to the Ginzburg-Landau equation and involves a subcritical exponent when λ1>0. For λ1≥ 0 and λ2∈ R, we prove the existence, non-negativity, and uniform boundedness of minimizers of J (u) . Then, we show that any minimizer is locally C1,α-continuous with some α∈ (0,1) and admits the optimal growth pp-1 near the free boundary. Finally, under the additional assumption that λ2>0, we establish non-degeneracy for minimizers near the free boundary and show that there exists at least one minimizer for which the corresponding free boundary has finite (N-1)-dimensional Hausdorff measure.