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Learning Equivariant Non-Local Electron Density Functionals

Machine Learning 2025-05-19 v3 Chemical Physics Computational Physics

Abstract

The accuracy of density functional theory hinges on the approximation of non-local contributions to the exchange-correlation (XC) functional. To date, machine-learned and human-designed approximations suffer from insufficient accuracy, limited scalability, or dependence on costly reference data. To address these issues, we introduce Equivariant Graph Exchange Correlation (EG-XC), a novel non-local XC functional based on equivariant graph neural networks (GNNs). Where previous works relied on semi-local functionals or fixed-size descriptors of the density, we compress the electron density into an SO(3)-equivariant nuclei-centered point cloud for efficient non-local atomic-range interactions. By applying an equivariant GNN on this point cloud, we capture molecular-range interactions in a scalable and accurate manner. To train EG-XC, we differentiate through a self-consistent field solver requiring only energy targets. In our empirical evaluation, we find EG-XC to accurately reconstruct `gold-standard' CCSD(T) energies on MD17. On out-of-distribution conformations of 3BPA, EG-XC reduces the relative MAE by 35% to 50%. Remarkably, EG-XC excels in data efficiency and molecular size extrapolation on QM9, matching force fields trained on 5 times more and larger molecules. On identical training sets, EG-XC yields on average 51% lower MAEs.

Keywords

Cite

@article{arxiv.2410.07972,
  title  = {Learning Equivariant Non-Local Electron Density Functionals},
  author = {Nicholas Gao and Eike Eberhard and Stephan Günnemann},
  journal= {arXiv preprint arXiv:2410.07972},
  year   = {2025}
}

Comments

International Conference on Representation Learning, 2025

R2 v1 2026-06-28T19:16:18.169Z