AlphaCrystal-II: Distance matrix based crystal structure prediction using deep learning
Abstract
Computational prediction of stable crystal structures has a profound impact on the large-scale discovery of novel functional materials. However, predicting the crystal structure solely from a material's composition or formula is a promising yet challenging task, as traditional ab initio crystal structure prediction (CSP) methods rely on time-consuming global searches and first-principles free energy calculations. Inspired by the recent success of deep learning approaches in protein structure prediction, which utilize pairwise amino acid interactions to describe 3D structures, we present AlphaCrystal-II, a novel knowledge-based solution that exploits the abundant inter-atomic interaction patterns found in existing known crystal structures. AlphaCrystal-II predicts the atomic distance matrix of a target crystal material and employs this matrix to reconstruct its 3D crystal structure. By leveraging the wealth of inter-atomic relationships of known crystal structures, our approach demonstrates remarkable effectiveness and reliability in structure prediction through comprehensive experiments. This work highlights the potential of data-driven methods in accelerating the discovery and design of new materials with tailored properties.
Keywords
Cite
@article{arxiv.2404.04810,
title = {AlphaCrystal-II: Distance matrix based crystal structure prediction using deep learning},
author = {Yuqi Song and Rongzhi Dong and Lai Wei and Qin Li and Jianjun Hu},
journal= {arXiv preprint arXiv:2404.04810},
year = {2024}
}
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16 pages