English

DeepRitzSplit Neural Operator for Phase-Field Models via Energy Splitting

Analysis of PDEs 2026-04-21 v1 Machine Learning Numerical Analysis Numerical Analysis

Abstract

The multi-scale and non-linear nature of phase-field models of solidification requires fine spatial and temporal discretization, leading to long computation times. This could be overcome with artificial-intelligence approaches. Surrogate models based on neural operators could have a lower computational cost than conventional numerical discretization methods. We propose a new neural operator approach that bridges classical convex-concave splitting schemes with physics-informed learning to accelerate the simulation of phase-field models. It consists of a Deep Ritz method, where a neural operator is trained to approximate a variational formulation of the phase-field model. By training the neural operator with an energy-splitting variational formulation, we enforce the energy dissipation property of the underlying models. We further introduce a custom Reaction-Diffusion Neural Operator (RDNO) architecture, adapted to the operators of the model equations. We successfully apply the deep learning approach to the isotropic Allen-Cahn equation and to anisotropic dendritic growth simulation. We demonstrate that our physically-informed training provides better generalization in out-of-distribution evaluations than data-driven training, while achieving faster inference than traditional Fourier spectral methods.

Keywords

Cite

@article{arxiv.2604.18261,
  title  = {DeepRitzSplit Neural Operator for Phase-Field Models via Energy Splitting},
  author = {Chih-Kang Huang and Ludovick Gagnon and Miha Založnik and Benoît Appolaire},
  journal= {arXiv preprint arXiv:2604.18261},
  year   = {2026}
}
R2 v1 2026-07-01T12:18:22.784Z