Accessing ultrastable glass via a bulk transformation

Hengtong Bu; Hengwei Luan; Jingyi Kang; Jili Jia; Wenhui Guo; Yunshuai Su; Huaping Ding; Hsiang Shun Chang; Ranbin Wang; You Wu; Lingxiang Shi; Pan Gong; Qiaoshi Zeng; Yang Shao; Kefu Yao

doi:10.1038/s41467-024-55367-8

Accessing ultrastable glass via a bulk transformation

Hengtong Bu
, Hengwei Luan
, Jingyi Kang
, Jili Jia
, Wenhui Guo
, Yunshuai Su
, Huaping Ding
, Hsiang Shun Chang
, Ranbin Wang
, You Wu
, Lingxiang Shi
, Pan Gong
, Qiaoshi Zeng
, Yang Shao^*
, Kefu Yao^*

^*Corresponding author for this work

Tsinghua University
City University of Hong Kong
Huazhong University of Science and Technology
Center for High Pressure Science & Technology Advanced Research
Institute for Shanghai Advanced Research in Physical Sciences (SHARPS)

Research output: Contribution to journal › Article › peer-review

10 Citations (Scopus)

Abstract

As a medium to understand the nature of glass transition, ultrastable glasses have garnered increasing attention for their significance in fundamental science and technological applications. Most studies have produced ultrastable glasses through a surface-controlled process using physical vapor deposition. Here, we demonstrate an approach to accessing ultrastable glasses via the glass-to-glass transition, a bulk transformation that is inherently free from size constraints and anisotropy. The resulting ultrastable glass exhibits a significantly enhanced density (improved by 2.3%), along with high thermodynamic, kinetic, and mechanical stability. Furthermore, we propose that this method of accessing ultrastable glasses is general for metallic glasses, based on the examination of the competitive relationship between the glass-to-glass transition and crystallization. This strategy is expected to facilitate the proliferation of the ultrastable glass family, helping to resolve the instability issues of glass materials and devices and deepen our understanding of glasses and the glass transition.

Original language	English
Article number	562
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-55367-8
Publication status	Published - Dec 2025
Externally published	Yes

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title = "Accessing ultrastable glass via a bulk transformation",

abstract = "As a medium to understand the nature of glass transition, ultrastable glasses have garnered increasing attention for their significance in fundamental science and technological applications. Most studies have produced ultrastable glasses through a surface-controlled process using physical vapor deposition. Here, we demonstrate an approach to accessing ultrastable glasses via the glass-to-glass transition, a bulk transformation that is inherently free from size constraints and anisotropy. The resulting ultrastable glass exhibits a significantly enhanced density (improved by 2.3\%), along with high thermodynamic, kinetic, and mechanical stability. Furthermore, we propose that this method of accessing ultrastable glasses is general for metallic glasses, based on the examination of the competitive relationship between the glass-to-glass transition and crystallization. This strategy is expected to facilitate the proliferation of the ultrastable glass family, helping to resolve the instability issues of glass materials and devices and deepen our understanding of glasses and the glass transition.",

author = "Hengtong Bu and Hengwei Luan and Jingyi Kang and Jili Jia and Wenhui Guo and Yunshuai Su and Huaping Ding and Chang, \{Hsiang Shun\} and Ranbin Wang and You Wu and Lingxiang Shi and Pan Gong and Qiaoshi Zeng and Yang Shao and Kefu Yao",

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doi = "10.1038/s41467-024-55367-8",

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AU - Bu, Hengtong

AU - Luan, Hengwei

AU - Kang, Jingyi

AU - Jia, Jili

AU - Guo, Wenhui

AU - Su, Yunshuai

AU - Ding, Huaping

AU - Chang, Hsiang Shun

AU - Wang, Ranbin

AU - Wu, You

AU - Shi, Lingxiang

AU - Gong, Pan

AU - Zeng, Qiaoshi

AU - Shao, Yang

AU - Yao, Kefu

PY - 2025/12

Y1 - 2025/12

N2 - As a medium to understand the nature of glass transition, ultrastable glasses have garnered increasing attention for their significance in fundamental science and technological applications. Most studies have produced ultrastable glasses through a surface-controlled process using physical vapor deposition. Here, we demonstrate an approach to accessing ultrastable glasses via the glass-to-glass transition, a bulk transformation that is inherently free from size constraints and anisotropy. The resulting ultrastable glass exhibits a significantly enhanced density (improved by 2.3%), along with high thermodynamic, kinetic, and mechanical stability. Furthermore, we propose that this method of accessing ultrastable glasses is general for metallic glasses, based on the examination of the competitive relationship between the glass-to-glass transition and crystallization. This strategy is expected to facilitate the proliferation of the ultrastable glass family, helping to resolve the instability issues of glass materials and devices and deepen our understanding of glasses and the glass transition.

AB - As a medium to understand the nature of glass transition, ultrastable glasses have garnered increasing attention for their significance in fundamental science and technological applications. Most studies have produced ultrastable glasses through a surface-controlled process using physical vapor deposition. Here, we demonstrate an approach to accessing ultrastable glasses via the glass-to-glass transition, a bulk transformation that is inherently free from size constraints and anisotropy. The resulting ultrastable glass exhibits a significantly enhanced density (improved by 2.3%), along with high thermodynamic, kinetic, and mechanical stability. Furthermore, we propose that this method of accessing ultrastable glasses is general for metallic glasses, based on the examination of the competitive relationship between the glass-to-glass transition and crystallization. This strategy is expected to facilitate the proliferation of the ultrastable glass family, helping to resolve the instability issues of glass materials and devices and deepen our understanding of glasses and the glass transition.

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JO - Nature Communications

JF - Nature Communications

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Accessing ultrastable glass via a bulk transformation

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