Stationary level surfaces and Liouville-type theorems characterizing hyperplanes

Abstract

We consider an entire graph S in RN+1 of a continuous real function f over RN with N 1. Let be an unbounded domain in RN+1 with boundary S. Consider nonlinear diffusion equations of the form ∂t U= φ(U) containing the heat equation. Let U be the solution of either the initial-boundary value problem over where the initial value equals zero and the boundary value equals 1, or the Cauchy problem where the initial data is the characteristic function of the set RN+1 . The problem we consider is to characterize S in such a way that there exists a stationary level surface of U in . We introduce a new class A of entire graphs S and, by using the sliding method, we show that S∈ A must be a hyperplane if there exists a stationary level surface of U in . This is an improvement of the previous result. Next, we consider the heat equation in particular and we introduce the class B of entire graphs S of functions f such that each |f(x)-f(y)|: |x-y| 1 is bounded. With the help of the theory of viscosity solutions, we show that S ∈ B must be a hyperplane if there exists a stationary isothermic surface of U in . This is a considerable improvement of the previous result. Related to the problem, we consider a class W of Weingarten hypersurfaces in RN+1 with N 1. Then we show that, if S belongs to W in the viscosity sense and S satisfies some natural geometric condition, then S ∈ B must be a hyperplane. This is also a considerable improvement of the previous result.