A Revisit of The Energy Quadratization Method with A Relaxation Technique

TL;DR

This paper enhances the energy quadratization (EQ) method by adding a relaxation technique that improves accuracy and stability while maintaining its computational efficiency and energy stability properties.

Contribution

It introduces a relaxation technique to the EQ method, ensuring the preservation of the original energy law and improving accuracy without significant computational cost.

Findings

The relaxed-EQ method maintains energy stability.

It accurately preserves the original energy law.

Effective in phase field models.

Abstract

This letter revisits the energy quadratization (EQ) method by introducing a novel and essential relaxation technique to improve its accuracy and stability. The EQ method has witnessed significant popularity in the past few years. Though acknowledging its effectiveness in designing energy-stable schemes for thermodynamically consistent models, the primary known drawback is apparent, i.e., its preserves a "modified" energy law represented by auxiliary variables instead of the original variables. Truncation errors are introduced during numerical calculations so that the numerical solutions of the auxiliary variables are no longer equivalent to their original continuous definitions. Even though the "modified" energy dissipation law is preserved, the original energy dissipation law is not guaranteed. In this paper, we overcome this issue by introducing a relaxation technique. The computational cost of this extra technique is negligible compared with the baseline EQ method. Meanwhile, the relaxed-EQ method holds all the baseline EQ method's good properties, such as linearity and unconditionally energy stability. Then we apply the relaxed-EQ method to several widely-used phase field models to highlight its effectiveness.