Exponentially slow motion of interface layers for the one-dimensional Allen-Cahn equation with nonlinear phase-dependent diffusivity

Abstract

This paper considers a one-dimensional generalized Allen-Cahn equation of the form \[ ut = 2 (D(u)ux)x - f(u), \] where >0 is constant, D=D(u) is a positive, uniformly bounded below diffusivity coefficient that depends on the phase field u and f(u) is a reaction function that can be derived from a double-well potential with minima at two pure phases u = α and u = β. It is shown that interface layers (namely, solutions that are equal to α or β except at a finite number of thin transitions of width ) persist for an exponentially long time proportional to (C/), where C > 0 is a constant. In other words, the emergence and persistence of metastable patterns for this class of equations is established. For that purpose, we prove energy bounds for a renormalized effective energy potential of Ginzburg-Landau type. Numerical simulations, which confirm the analytical results, are also provided.