A decreasing upper bound of energy for time-fractional phase-field equations

TL;DR

This paper establishes a decreasing upper bound for the energy of time-fractional phase-field equations, demonstrating energy decay over time and providing stability insights for numerical schemes.

Contribution

It introduces a novel decreasing upper bound of energy for time-fractional phase-field equations, applicable to models like Allen-Cahn and Cahn-Hilliard, with stability analysis for numerical schemes.

Findings

The energy upper bound decreases over time and matches the original energy at initial and infinite times.

First-order L1 and second-order L2 schemes exhibit similar decreasing modified energies.

Numerical results confirm the theoretical energy decay and stability properties.

Abstract

In this article, we study the energy dissipation property of time-fractional Allen-Cahn equation. We propose a decreasing upper bound of energy that decreases with respect to time and coincides with the original energy at $t = 0$ and as $t$ tends to $\infty$. This upper bound can also be viewed as a nonlocal-in-time modified energy, the summation of the original energy and an accumulation term due to the memory effect of time fractional derivative. In particular, this indicates that the original energy indeed decays w.r.t. time in a small neighborhood at $t=0$. We illustrate the theory mainly with the time-fractional Allen-Cahn equation, but it could be applied to other time-fractional phase-field models such as the Cahn-Hilliard equation. On the discrete level, the first-order L1 and second-order L2 schemes for time-fractional Allen-Cahn equation have similar decreasing modified energies, so that the stability can be established. Some numerical results are provided to illustrate the behavior of this modified energy and to verify our theoretical results.