Local and global existence of solutions to a fourth-order parabolic equation modeling kinetic roughening and coarsening in thin films

Abstract

In this paper we study both the Cauchy problem and the initial boundary value problem for the equation ∂tu+div(∇ u- g(∇ u))=0. This equation has been proposed as a continuum model for kinetic roughening and coarsening in thin films. In the Cauchy problem, we obtain that local existence of a weak solution is guaranteed as long as the vector-valued function g is continuous and the initial datum u0 lies in C1(RN) with ∇ u0(x) being uniformly continuous and bounded on RN and that the global existence assertion also holds true if we assume that g is locally Lipschitz and satisfies the growth condition | g() |≤ c||α for some c>0, α∈ (2, 3), RN|∇ u0|<∞, and the norm of u0 in the space L(α-1)N3-α(RN) is sufficiently small. This is done by exploring various properties of the biharmonic heat kernel. In the initial boundary value problem, we assume that g is continuous and satisfies the growth condition | g() |≤ c||α+c for some c, α∈ (0,∞). Our investigations reveal that if α≤ 1 we have global existence of a weak solution, while if 1<α<N2+2N+4N2 only a local existence theorem can be established. Our method here is based upon a new interpolation inequality, which may be of interest in its own right.