Long-time behavior of a nonlocal Cahn-Hilliard equation with nonlocal dynamic boundary condition and singular potentials

Abstract

We investigate the long-time behavior of a nonlocal Cahn-Hilliard equation in a bounded domain ⊂Rd (d∈\2,3\), subject to a kinetic rate-dependent nonlocal dynamic boundary condition. The kinetic rate 1/L, with L∈[0,+∞), distinguishes different types of bulk-surface interactions. For general singular potentials, including the physically relevant logarithmic potential, we establish the existence of a global attractor AmL in a suitable complete metric space for any L∈[0,+∞). Moreover, we verify that the global attractor Am0 is stable with respect to perturbations AmL for small L>0. When L∈(0,+∞), based on the strict separation property of global weak solutions, we further prove the existence of exponential attractors via a short-trajectory type technique, which also implies that the global attractor has finite fractal dimension. Finally, for this case, we show that every global weak solution converges to a single equilibrium in L∞ as time goes to infinity, using a generalized ojasiewicz-Simon inequality and an Alikakos-Moser type iteration.