MACE: Higher Order Equivariant Message Passing Neural Networks for Fast and Accurate Force Fields
Abstract
Creating fast and accurate force fields is a long-standing challenge in computational chemistry and materials science. Recently, Equivariant Message Passing Neural Networks (MPNNs) have emerged as a powerful tool for building machine learning interatomic potentials, outperforming other approaches in terms of accuracy. However, they suffer from high computational cost and poor scalability. Moreover, most MPNNs only pass two-body messages leading to an intricate relationship between the number of layers and the expressivity of the features. This work introduces MACE, a new equivariant MPNN model that uses higher order messages, and demonstrates that this leads to an improved learning law. We show that by using four-body messages, the required number of message passing iterations reduces to just one, resulting in a fast and highly parallelizable model, reaching or exceeding state of the art accuracy on the rMD17 and 3BPA benchmark tasks. Our implementation is available at https://github.com/ACEsuit/mace.
Cite
Text
Batatia et al. "MACE: Higher Order Equivariant Message Passing Neural Networks for Fast and Accurate Force Fields." Neural Information Processing Systems, 2022.Markdown
[Batatia et al. "MACE: Higher Order Equivariant Message Passing Neural Networks for Fast and Accurate Force Fields." Neural Information Processing Systems, 2022.](https://mlanthology.org/neurips/2022/batatia2022neurips-mace/)BibTeX
@inproceedings{batatia2022neurips-mace,
title = {{MACE: Higher Order Equivariant Message Passing Neural Networks for Fast and Accurate Force Fields}},
author = {Batatia, Ilyes and Kovacs, David P and Simm, Gregor and Ortner, Christoph and Csanyi, Gabor},
booktitle = {Neural Information Processing Systems},
year = {2022},
url = {https://mlanthology.org/neurips/2022/batatia2022neurips-mace/}
}