SLICES-PLUS: A crystal representation leveraging spatial symmetry

Baoning WANG; Zhiyuan XU; Zhiyu HAN; Qiwen NIE; Xi CHEN; Hang XIAO; Gang YAN

doi:10.1016/j.matdes.2025.113856

SLICES-PLUS: A crystal representation leveraging spatial symmetry

Baoning WANG, Zhiyuan XU, Zhiyu HAN, Qiwen NIE, Xi CHEN, Hang XIAO, Gang YAN

School of Interdisciplinary Studies

Research output: Journal Publications › Journal Article (refereed) › peer-review

Abstract

In recent years, the realm of crystalline materials has witnessed a surge in the development of generative models, predominantly aimed at the inverse design of crystals with tailored physical properties. However, spatial symmetry, which serves as a significant inductive bias, is often not optimally harnessed in the design process. This oversight tends to result in crystals with lower symmetry, potentially limiting the practical applications of certain functional materials. To bridge this gap, we introduce SLICES-PLUS, an enhanced variant of SLICES that emphasizes spatial symmetry. Our experiments in classification and generation have shown that SLICES-PLUS exhibits greater sensitivity and robustness in learning crystal symmetries compared to the original SLICES. Furthermore, by integrating SLICES-PLUS with a customized MatterGPT model, we have demonstrated its exceptional capability to target the specific physical properties and crystal systems with precision. Finally, we explore autoregressive generation towards multiple elastic properties in few-shot learning. Our research represents a significant step forward in the realm of computational materials discovery.

Original language	English
Article number	113856
Journal	International Journal of Materials in Engineering Applications
Volume	253
Early online date	20 Mar 2025
DOIs	https://doi.org/10.1016/j.matdes.2025.113856
Publication status	E-pub ahead of print - 20 Mar 2025

Bibliographical note

We thank X.Ru, X.Wu, Z.Wang and Y.Xu for helpful discussion. We thank S. Lu for his assistance in applying DFT calculations.

Publisher Copyright:
© 2025 The Authors

Funding

G.Y. is supported by the National Natural Science Foundation of China (Grant No. T2225022, No. 12350710786, and No. 62088101), Shanghai Municipal Education Commission (AI-Empowered Dsipline Development Initiative), and the Fundamental Research Funds for the Central Universities. H.X. acknowledges the support from the 6th Young Elite Scientist Sponsorship Program by China Association for Science and Technology (Grant No. 2020QNRC001), National Natural Science Foundation of China (Grant No. 22203066).

Keywords

Crystal symmetry
SLICES-PLUS
MatterGPT
Inverse design

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Cite this

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title = "SLICES-PLUS: A crystal representation leveraging spatial symmetry",

abstract = "In recent years, the realm of crystalline materials has witnessed a surge in the development of generative models, predominantly aimed at the inverse design of crystals with tailored physical properties. However, spatial symmetry, which serves as a significant inductive bias, is often not optimally harnessed in the design process. This oversight tends to result in crystals with lower symmetry, potentially limiting the practical applications of certain functional materials. To bridge this gap, we introduce SLICES-PLUS, an enhanced variant of SLICES that emphasizes spatial symmetry. Our experiments in classification and generation have shown that SLICES-PLUS exhibits greater sensitivity and robustness in learning crystal symmetries compared to the original SLICES. Furthermore, by integrating SLICES-PLUS with a customized MatterGPT model, we have demonstrated its exceptional capability to target the specific physical properties and crystal systems with precision. Finally, we explore autoregressive generation towards multiple elastic properties in few-shot learning. Our research represents a significant step forward in the realm of computational materials discovery.",

keywords = "Crystal symmetry, SLICES-PLUS, MatterGPT, Inverse design",

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note = "We thank X.Ru, X.Wu, Z.Wang and Y.Xu for helpful discussion. We thank S. Lu for his assistance in applying DFT calculations. Publisher Copyright: {\textcopyright} 2025 The Authors",

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doi = "10.1016/j.matdes.2025.113856",

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AU - WANG, Baoning

AU - XU, Zhiyuan

AU - HAN, Zhiyu

AU - NIE, Qiwen

AU - CHEN, Xi

AU - XIAO, Hang

AU - YAN, Gang

PY - 2025/3/20

Y1 - 2025/3/20

N2 - In recent years, the realm of crystalline materials has witnessed a surge in the development of generative models, predominantly aimed at the inverse design of crystals with tailored physical properties. However, spatial symmetry, which serves as a significant inductive bias, is often not optimally harnessed in the design process. This oversight tends to result in crystals with lower symmetry, potentially limiting the practical applications of certain functional materials. To bridge this gap, we introduce SLICES-PLUS, an enhanced variant of SLICES that emphasizes spatial symmetry. Our experiments in classification and generation have shown that SLICES-PLUS exhibits greater sensitivity and robustness in learning crystal symmetries compared to the original SLICES. Furthermore, by integrating SLICES-PLUS with a customized MatterGPT model, we have demonstrated its exceptional capability to target the specific physical properties and crystal systems with precision. Finally, we explore autoregressive generation towards multiple elastic properties in few-shot learning. Our research represents a significant step forward in the realm of computational materials discovery.

AB - In recent years, the realm of crystalline materials has witnessed a surge in the development of generative models, predominantly aimed at the inverse design of crystals with tailored physical properties. However, spatial symmetry, which serves as a significant inductive bias, is often not optimally harnessed in the design process. This oversight tends to result in crystals with lower symmetry, potentially limiting the practical applications of certain functional materials. To bridge this gap, we introduce SLICES-PLUS, an enhanced variant of SLICES that emphasizes spatial symmetry. Our experiments in classification and generation have shown that SLICES-PLUS exhibits greater sensitivity and robustness in learning crystal symmetries compared to the original SLICES. Furthermore, by integrating SLICES-PLUS with a customized MatterGPT model, we have demonstrated its exceptional capability to target the specific physical properties and crystal systems with precision. Finally, we explore autoregressive generation towards multiple elastic properties in few-shot learning. Our research represents a significant step forward in the realm of computational materials discovery.

KW - Crystal symmetry

KW - SLICES-PLUS

KW - MatterGPT

KW - Inverse design

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DO - 10.1016/j.matdes.2025.113856

M3 - Journal Article (refereed)

SN - 0261-3069

VL - 253

JO - International Journal of Materials in Engineering Applications

JF - International Journal of Materials in Engineering Applications

M1 - 113856

ER -

SLICES-PLUS: A crystal representation leveraging spatial symmetry

Abstract

Bibliographical note

Funding

Keywords

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