Physics-Informed Long-Range Coulomb Correction for Machine-learning Hamiltonians
Abstract
Machine-learning electronic Hamiltonians achieve orders-of-magnitude speedups over density-functional theory, yet current models omit long-range Coulomb interactions that govern physics in polar crystals and heterostructures. We derive closed-form long-range Hamiltonian matrix elements in a nonorthogonal atomic-orbital basis through variational decomposition of the electrostatic energy, deriving a variationally consistent mapping from the electron density matrix to effective atomic charges. We implement this framework in HamGNN-LR, a dual-channel architecture combining E(3)-equivariant message passing with reciprocal-space Ewald summation. Benchmarks demonstrate that physics-based long-range corrections are essential: purely data-driven attention mechanisms fail to capture macroscopic electrostatic potentials. Benchmarks on polar ZnO slabs, CdSe/ZnS heterostructures, and GaN/AlN superlattices show two- to threefold error reductions and robust transferability to systems far beyond training sizes, eliminating the characteristic staircase artifacts that plague short-range models in the presence of built-in electric fields.
Cite
@article{arxiv.2603.20007,
title = {Physics-Informed Long-Range Coulomb Correction for Machine-learning Hamiltonians},
author = {Yang Zhong and Xiwen Li and Xingao Gong and Hongjun Xiang},
journal= {arXiv preprint arXiv:2603.20007},
year = {2026}
}
Comments
9 pages,3 figures