Ab initio study of magnetic superstructures (e.g., magnetic skyrmion) is indispensable to the research of novel materials but bottlenecked by its formidable computational cost. For solving the bottleneck problem, we develop a deep equivariant neural network method (named xDeepH) to represent density functional theory Hamiltonian HDFT as a function of atomic and magnetic structures and apply neural networks for efficient electronic structure calculation. Intelligence of neural networks is optimized by incorporating a priori knowledge about the important locality and symmetry properties into the method. Particularly, we design a neural-network architecture fully preserving all equivalent requirements on HDFT by the Euclidean and time-reversal symmetries (E(3)×{I,T}), which is essential to improve method performance. High accuracy (sub-meV error) and good transferability of xDeepH are shown by systematic experiments on nanotube, spin-spiral, and Moir\'{e} magnets, and the capability of studying magnetic skyrmion is also demonstrated. The method could find promising applications in magnetic materials research and inspire development of deep-learning ab initio methods.
@article{arxiv.2211.10604,
title = {Deep-learning electronic-structure calculation of magnetic superstructures},
author = {He Li and Zechen Tang and Xiaoxun Gong and Nianlong Zou and Wenhui Duan and Yong Xu},
journal= {arXiv preprint arXiv:2211.10604},
year = {2023}
}