Capturing Global Features of Crystals from Their Bond Networks

Qianxiang Ai; Sartaaj Takrim  Khan; Senja Barthel; Seyed Mohamad Moosavi

Capturing Global Features of Crystals from Their Bond Networks

Qianxiang Ai
, Sartaaj Takrim Khan
, Senja Barthel
, Seyed Mohamad Moosavi

Mathematics

Research output: Chapter in Book / Report / Conference proceeding › Conference contribution › Academic › peer-review

Abstract

Representing crystal structures for machine learning property prediction traditionally relies on either composition-based methods or structure-based graph neural networks (GNNs). While these methods have been successful in predicting certain properties, they fall short in accurately capturing the periodicity of crystal structures, particularly long-range information. In this work, we show that topological features derived from labeled quotient graphs (LQGs)--finite graph representations that encode bond topology without relying on real-space geometric information--can effectively predict non-local properties, i.e., properties that are not solely determined by individual local atomic environments. Using a dataset of 25,000 silica zeolite structures, we demonstrate that XGBoost models trained on LQG-derived topological features (XGB-LQG) outperform conventional GNNs (CGCNN, MEGNet) in predicting non-local properties. Furthermore, hybrid architectures that combine GNN embeddings with LQG features achieve intermediate performance, highlighting the complementary nature of geometric and topological representations. Our results establish LQGs as a powerful representation for incorporating bond topology into crystal property prediction.

Original language	English
Title of host publication	Contributions to ICLR 2025 Workshop AI4MAT
Subtitle of host publication	[Proceedings]
Publisher	ICLR
Pages	1-12
Number of pages	12
ISBN (Electronic)	9798331320850
Publication status	Published - 2025
Event	13th International Conference on Learning Representations, ICLR 2025 - Singapore, Singapore Duration: 24 Apr 2025 → 28 Apr 2025

Conference

Conference	13th International Conference on Learning Representations, ICLR 2025
Country/Territory	Singapore
City	Singapore
Period	24/04/25 → 28/04/25

Funding

Q.A. acknowledges the support by the National Institutes of Health under award number U18TR004149. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health. Q.A. thanks the computation resource generously provided by Dr. Connor W. Coley’s group and helpful discussions with Dr. Runzhong Wang. This work received support from the National Research Council of Canada (NRC) under the Materials for Clean Fuels Challenge Program (grant number MCF-146). In addition, the project received support from the University of Toronto’s Acceleration Consortium through the Canada First Research Excellence Fund under Grant number CFREF-2022-00042 and from the Data Science Institute (DSI) at the University of Toronto. S.M.M. research program receives financial support from Natural Sciences and Engineering Research Council of Canada (NSERC) through the discovery program

Keywords

AI guided materials design
bond topology
quotient graph
crystal property prediction

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https://openreview.net/forum?id=wLSmBbYDY5Licence: CC BY

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@inproceedings{29d4c3a674a34e0bab3504a4218e1443,

title = "Capturing Global Features of Crystals from Their Bond Networks",

abstract = "Representing crystal structures for machine learning property prediction traditionally relies on either composition-based methods or structure-based graph neural networks (GNNs). While these methods have been successful in predicting certain properties, they fall short in accurately capturing the periodicity of crystal structures, particularly long-range information. In this work, we show that topological features derived from labeled quotient graphs (LQGs)--finite graph representations that encode bond topology without relying on real-space geometric information--can effectively predict non-local properties, i.e., properties that are not solely determined by individual local atomic environments. Using a dataset of 25,000 silica zeolite structures, we demonstrate that XGBoost models trained on LQG-derived topological features (XGB-LQG) outperform conventional GNNs (CGCNN, MEGNet) in predicting non-local properties. Furthermore, hybrid architectures that combine GNN embeddings with LQG features achieve intermediate performance, highlighting the complementary nature of geometric and topological representations. Our results establish LQGs as a powerful representation for incorporating bond topology into crystal property prediction.",

keywords = "AI guided materials design, bond topology, quotient graph, crystal property prediction",

author = "Qianxiang Ai and Khan, \{Sartaaj Takrim\} and Senja Barthel and Moosavi, \{Seyed Mohamad\}",

year = "2025",

language = "English",

pages = "1--12",

booktitle = "Contributions to ICLR 2025 Workshop AI4MAT",

publisher = "ICLR",

note = "13th International Conference on Learning Representations, ICLR 2025 ; Conference date: 24-04-2025 Through 28-04-2025",

}

TY - GEN

T1 - Capturing Global Features of Crystals from Their Bond Networks

AU - Ai, Qianxiang

AU - Khan, Sartaaj Takrim

AU - Barthel, Senja

AU - Moosavi, Seyed Mohamad

PY - 2025

Y1 - 2025

N2 - Representing crystal structures for machine learning property prediction traditionally relies on either composition-based methods or structure-based graph neural networks (GNNs). While these methods have been successful in predicting certain properties, they fall short in accurately capturing the periodicity of crystal structures, particularly long-range information. In this work, we show that topological features derived from labeled quotient graphs (LQGs)--finite graph representations that encode bond topology without relying on real-space geometric information--can effectively predict non-local properties, i.e., properties that are not solely determined by individual local atomic environments. Using a dataset of 25,000 silica zeolite structures, we demonstrate that XGBoost models trained on LQG-derived topological features (XGB-LQG) outperform conventional GNNs (CGCNN, MEGNet) in predicting non-local properties. Furthermore, hybrid architectures that combine GNN embeddings with LQG features achieve intermediate performance, highlighting the complementary nature of geometric and topological representations. Our results establish LQGs as a powerful representation for incorporating bond topology into crystal property prediction.

AB - Representing crystal structures for machine learning property prediction traditionally relies on either composition-based methods or structure-based graph neural networks (GNNs). While these methods have been successful in predicting certain properties, they fall short in accurately capturing the periodicity of crystal structures, particularly long-range information. In this work, we show that topological features derived from labeled quotient graphs (LQGs)--finite graph representations that encode bond topology without relying on real-space geometric information--can effectively predict non-local properties, i.e., properties that are not solely determined by individual local atomic environments. Using a dataset of 25,000 silica zeolite structures, we demonstrate that XGBoost models trained on LQG-derived topological features (XGB-LQG) outperform conventional GNNs (CGCNN, MEGNet) in predicting non-local properties. Furthermore, hybrid architectures that combine GNN embeddings with LQG features achieve intermediate performance, highlighting the complementary nature of geometric and topological representations. Our results establish LQGs as a powerful representation for incorporating bond topology into crystal property prediction.

KW - AI guided materials design

KW - bond topology

KW - quotient graph

KW - crystal property prediction

UR - https://openreview.net/group?id=ICLR.cc/2025/Workshop/AI4MAT#tab-accept-spotlight

M3 - Conference contribution

SP - 1

EP - 12

BT - Contributions to ICLR 2025 Workshop AI4MAT

PB - ICLR

T2 - 13th International Conference on Learning Representations, ICLR 2025

Y2 - 24 April 2025 through 28 April 2025

ER -

Capturing Global Features of Crystals from Their Bond Networks

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Keywords

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