Weak solutions to the parabolic p-Laplace equation in a moving domain under a Neumann type boundary condition

Abstract

This paper studies the parabolic p-Laplace equation with p>2 in a moving domain under a Neumann type boundary condition corresponding to the total mass conservation. We establish the existence and uniqueness of a weak solution by the Galerkin method in evolving Bochner spaces and a monotonicity argument. The main difficulty is in characterizing the weak limit of the nonlinear gradient term, where we need to deal with a term which comes from the boundary condition and cannot be absorbed into a monotone operator. To overcome this difficulty, we prove a uniform-in-time Friedrichs type inequality on a moving domain with time-dependent basis functions and make use of it to get the strong convergence of approximate solutions. We also show that the time derivative exists in the L2 sense when given data have a better regularity, and discuss extension of the existence and uniqueness results to a Leray-Lions type operator.