Equivariant Parameter Sharing for Porous Crystalline Materials

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Abstract

Efficiently predicting properties of porous crystalline materials has great potential to accelerate the high throughput screening process for developing new materials, as simulations carried out using first principles models are often computationally expensive. To effectively make use of Deep Learning methods to model these materials, we need to utilize the symmetries present in crystals, which are defined by their space group. Existing methods for crystal property prediction either have symmetry constraints that are too restrictive or only incorporate symmetries between unit cells. In addition, these models do not explicitly model the porous structure of the crystal. In this paper, we develop a model which incorporates the symmetries of the unit cell of a crystal in its architecture and explicitly models the porous structure. We evaluate our model by predicting the heat of adsorption of CO2 for different configurations of the mordenite and ZSM-5 zeolites. Our results confirm that our method performs better than existing methods for crystal property prediction and that the inclusion of pores results in a more efficient model.

Original languageEnglish
Title of host publicationAdvances in Intelligent Data Analysis XXII
Subtitle of host publication22nd International Symposium on Intelligent Data Analysis, IDA 2024, Stockholm, Sweden, April 24–26, 2024, Proceedings, Part I
EditorsIoanna Miliou, Nico Piatkowski, Panagiotis Papapetrou
Place of PublicationCham
PublisherSpringer
Pages129-140
Number of pages12
ISBN (Electronic)978-3-031-58547-0
ISBN (Print)978-3-031-58546-3
DOIs
Publication statusPublished - 16 Apr 2024
Event22nd International Symposium on Intelligent Data Analysis, IDA 2024 - Stockholm, Sweden
Duration: 24 Apr 202426 Apr 2024

Publication series

NameLecture Notes in Computer Science (LNCS)
Volume14641
ISSN (Print)0302-9743
ISSN (Electronic)1611-3349

Conference

Conference22nd International Symposium on Intelligent Data Analysis, IDA 2024
Country/TerritorySweden
CityStockholm
Period24/04/2426/04/24

Keywords

  • Graph Neural Networks
  • Porous Materials
  • Symmetries

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