Black and Gray Box Learning of Amplitude Equations: Application to Phase Field Systems
This work addresses the problem of modeling complex interfacial dynamics in phase field systems for researchers in computational physics and materials science, offering an incremental improvement by combining data-driven corrections with existing analytical models.
The authors developed a data-driven method to learn surrogate models for amplitude equations, specifically for phase field interfacial dynamics, and showed that these models outperform traditional analytical approximations when those approximations become inaccurate beyond their validity regimes.
We present a data-driven approach to learning surrogate models for amplitude equations, and illustrate its application to interfacial dynamics of phase field systems. In particular, we demonstrate learning effective partial differential equations describing the evolution of phase field interfaces from full phase field data. We illustrate this on a model phase field system, where analytical approximate equations for the dynamics of the phase field interface (a higher order eikonal equation and its approximation, the Kardar-Parisi-Zhang (KPZ) equation) are known. For this system, we discuss data-driven approaches for the identification of equations that accurately describe the front interface dynamics. When the analytical approximate models mentioned above become inaccurate, as we move beyond the region of validity of the underlying assumptions, the data-driven equations outperform them. In these regimes, going beyond black-box identification, we explore different approaches to learn data-driven corrections to the analytically approximate models, leading to effective gray box partial differential equations.