Equivariant Evidential Deep Learning for Interatomic Potentials
Abstract
Uncertainty quantification (UQ) is critical for assessing the reliability of machine learning interatomic potentials (MLIPs) in molecular dynamics (MD) simulations, identifying extrapolation regimes and enabling uncertainty-aware workflows such as active learning for training dataset construction. Existing UQ approaches for MLIPs are often limited by high computational cost or suboptimal performance. Evidential deep learning (EDL) provides a theoretically grounded single-model alternative that determines both aleatoric and epistemic uncertainty in a single forward pass. However, extending evidential formulations from scalar targets to vector-valued quantities such as atomic forces introduces substantial challenges, particularly in maintaining statistical self-consistency under rotational transformations. To address this, we propose \textit{Equivariant Evidential Deep Learning for Interatomic Potentials} (IP), a backbone-agnostic framework that models atomic forces and their uncertainty jointly by representing uncertainty as a full symmetric positive definite covariance tensor that transforms equivariantly under rotations. Experiments on diverse molecular benchmarks show that IP provides a stronger accuracy-efficiency-reliability balance than the non-equivariant evidential baseline and the widely used ensemble method. It also achieves better data efficiency through the fully equivariant architecture while retaining single-model inference efficiency.
Cite
@article{arxiv.2602.10419,
title = {Equivariant Evidential Deep Learning for Interatomic Potentials},
author = {Zhongyao Wang and Taoyong Cui and Jiawen Zou and Shufei Zhang and Bo Yan and Wanli Ouyang and Weimin Tan and Mao Su},
journal= {arXiv preprint arXiv:2602.10419},
year = {2026}
}