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Hauptverfasser: Liu, Fangze, Chen, Zhantao, Liu, Tianyi, Song, Ruyi, Lin, Yu, Turner, Joshua J., Jia, Chunjing
Format: Preprint
Veröffentlicht: 2023
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2312.14485
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author Liu, Fangze
Chen, Zhantao
Liu, Tianyi
Song, Ruyi
Lin, Yu
Turner, Joshua J.
Jia, Chunjing
author_facet Liu, Fangze
Chen, Zhantao
Liu, Tianyi
Song, Ruyi
Lin, Yu
Turner, Joshua J.
Jia, Chunjing
contents Drawing inspiration from the achievements of natural language processing, we adopt self-supervised learning and utilize an equivariant graph neural network to develop a unified platform designed for training generative models capable of generating crystal structures, as well as efficiently adapting to downstream tasks in material property prediction. To mitigate the challenge of incorporating large-scale assessment on the reliability of generated structures into the training process, we utilize the generative adversarial network (GAN) with its discriminator being a cost-effective evaluator for the generated structures, resulting in notable improvements in model performance. We demonstrate the utility of our model in finding the optimal crystal structure under predefined conditions. Without reliance on properties acquired experimentally or numerically, our model further displays its capability to comprehend the mechanism of crystal structure formation through its ability to grouping chemically similar elements. Therefore, this paper extends an invitation to explore deeper into the scientific understanding of material structures through generative models, offering a fresh perspective on broadening the scope and efficacy of machine learning in material science.
format Preprint
id arxiv_https___arxiv_org_abs_2312_14485
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Self-Supervised Generative Models for Crystal Structures
Liu, Fangze
Chen, Zhantao
Liu, Tianyi
Song, Ruyi
Lin, Yu
Turner, Joshua J.
Jia, Chunjing
Materials Science
Drawing inspiration from the achievements of natural language processing, we adopt self-supervised learning and utilize an equivariant graph neural network to develop a unified platform designed for training generative models capable of generating crystal structures, as well as efficiently adapting to downstream tasks in material property prediction. To mitigate the challenge of incorporating large-scale assessment on the reliability of generated structures into the training process, we utilize the generative adversarial network (GAN) with its discriminator being a cost-effective evaluator for the generated structures, resulting in notable improvements in model performance. We demonstrate the utility of our model in finding the optimal crystal structure under predefined conditions. Without reliance on properties acquired experimentally or numerically, our model further displays its capability to comprehend the mechanism of crystal structure formation through its ability to grouping chemically similar elements. Therefore, this paper extends an invitation to explore deeper into the scientific understanding of material structures through generative models, offering a fresh perspective on broadening the scope and efficacy of machine learning in material science.
title Self-Supervised Generative Models for Crystal Structures
topic Materials Science
url https://arxiv.org/abs/2312.14485