Energy stable arbitrary order ETD-MS method for gradient flows with Lipschitz nonlinearity
Abstract
We present a methodology to construct efficient high-order in time accurate numerical schemes for a class of gradient flows with appropriate Lipschitz continuous nonlinearity. There are several ingredients to the strategy: the exponential time differencing (ETD), the multi-step (MS) methods, the idea of stabilization, and the technique of interpolation. They are synthesized to develop a generic order in time efficient linear numerical scheme with the help of an artificial regularization term of the form where is the positive definite linear part of the flow, is the uniform time step-size. The exponent is determined explicitly by the strength of the Lipschitz nonlinear term in relation to together with the desired temporal order of accuracy . To validate our theoretical analysis, the thin film epitaxial growth without slope selection model is examined with a fourth-order ETD-MS discretization in time and Fourier pseudo-spectral in space discretization. Our numerical results on convergence and energy stability are in accordance with our theoretical results.
Keywords
Cite
@article{arxiv.2102.10988,
title = {Energy stable arbitrary order ETD-MS method for gradient flows with Lipschitz nonlinearity},
author = {Wenbin Chen and Shufen Wang and Xiaoming Wang},
journal= {arXiv preprint arXiv:2102.10988},
year = {2021}
}