A DeGiorgi type conjecture for minimal solutions to a nonlinear Stokes equation

Abstract

We study the one-dimensional symmetry of solutions to the nonlinear Stokes equation cases - u+∇ W(u)=∇ p&in Rd,\\ ∇· u=0&in Rd, cases which are periodic in the d-1 last variables (living on the torus Td-1) and globally minimize the corresponding energy in =R× Td-1, i.e., E(u)=∫ 12 |∇ u|2+W(u)\, dx, ∇· u=0. Namely, we determine a class of nonlinear potentials W≥ 0 such that any global minimizer u of E connecting two zeros of W as x1∞ is one-dimensional, i.e., u depends only on the x1 variable. In particular, this class includes in dimension d=2 the nonlinearities W=w2 with w being an harmonic function or a solution to the wave equation, while in dimension d≥ 3, this class contains a perturbation of the Ginzburg-Landau potential as well as potentials W having d+1 wells with prescribed transition cost between the wells. For that, we develop a theory of calibrations relying on the notion of entropy (coming from scalar conservation laws). We also study the problem of the existence of global minimizers of E for general potentials W providing in particular compactness results for uniformly finite energy maps u in connecting two wells of W as x1∞.