Long time dynamics of solutions to p-Laplacian diffusion problems with bistable reaction terms

Abstract

This paper establishes the emergence of slowly moving transition layer solutions for the p-Laplacian (nonlinear) evolution equation, \[ ut = p(|ux|p-2ux)x - F'(u), x ∈ (a,b), \; t > 0, \] where >0 and p>1 are constants, driven by the action of a family of double-well potentials of the form \[ F(u)=12n |1-u2|n, \] indexed by n>1, n∈R with minima at two pure phases u = 1. The equation is endowed with initial conditions and boundary conditions of Neumann type. It is shown that interface layers, or solutions which initially are equal to 1 except at a finite number of thin transitions of width , persist for an exponentially long time in the critical case with n=p, and for an algebraically long time in the supercritical (or degenerate) case with n > p. For that purpose, energy bounds for a renormalized effective energy potential of Ginzburg-Landau type are established. In contrast, in the subcritical case with n<p, the transition layer solutions are stationary.