Water cluster triggered vitrification in HKUST-1 MOF crystal under pressure

Jianguo Sun; Chin Ho Kirk; Yunchuan Pu; Athulya S. Palakkal; Lewis Kien Juen Ting; Fei Wang; Kok Chan Chong; Tuo Wang; Saad Aldin Mohamed; Bin Liu; Jianwen Jiang; Anthony K. Cheetham; Dan Zhao; John Wang

doi:10.1002/inf2.70100

Water cluster triggered vitrification in HKUST-1 MOF crystal under pressure

Jianguo Sun (Co-first Author)
, Chin Ho Kirk (Co-first Author)
, Yunchuan Pu (Co-first Author)
, Athulya S. Palakkal (Co-first Author)
, Lewis Kien Juen Ting
, Fei Wang
, Kok Chan Chong
, Tuo Wang
, Saad Aldin Mohamed
, Bin Liu
, Jianwen Jiang^*
, Anthony K. Cheetham^*
, Dan Zhao^*
, John Wang^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

1 Citation (Scopus)

1 Downloads (CityUHK Scholars)

Abstract

Metal–organic framework (MOF) glasses feature several unique dynamic and thermodynamic properties that differentiate them from their crystalline counterparts. However, the formation of MOF glasses usually requires the melt-quenching of molten MOFs from relatively high temperatures. In practice, this approach is quite limited because most MOFs decompose below their melting points. Herein, we demonstrate a direct crystal-to-glass transition in HKUST-1 MOF that has been achieved at room temperature and a relatively low pressure of <1.0 GPa. The dramatic fall in the required pressure is shown to arise from the aggregation of coordinated polar water molecules to form water clusters that exhibit a pulling effect on the Cu–O_(ligand) bonds. Meanwhile, the departed fragment gets flipped unfavorably to prevent further regeneration of the bond. Accordingly, a grain boundary-free continuous porous framework in the glassy state is successfully formed and can be fabricated into membranes. Given their unique microporosity and grain boundary-free characteristics, such MOF glass membranes present new opportunities for chemical separation (both gases and liquids), electrochemistry, and catalysts, promising a new platform for MOF glasses. © 2026 The Author(s). InfoMat published by UESTC and John Wiley & Sons Australia, Ltd.

Original language	English
Article number	e70100
Number of pages	11
Journal	InfoMat
Volume	8
Issue number	3
Online published	15 Jan 2026
DOIs	https://doi.org/10.1002/inf2.70100
Publication status	Published - Mar 2026
Externally published	Yes

Funding

This work was supported by the National Research Foundation of Singapore, for research conducted at the National University of Singapore (NRF-CRP26-2021RS-0002).

Research Keywords

grain-boundary-free membrane
MOF glass
molecular separation
pressure-induced glass transition
water cluster

Publisher's Copyright Statement

This full text is made available under CC-BY 4.0. https://creativecommons.org/licenses/by/4.0/

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title = "Water cluster triggered vitrification in HKUST-1 MOF crystal under pressure",

abstract = "Metal–organic framework (MOF) glasses feature several unique dynamic and thermodynamic properties that differentiate them from their crystalline counterparts. However, the formation of MOF glasses usually requires the melt-quenching of molten MOFs from relatively high temperatures. In practice, this approach is quite limited because most MOFs decompose below their melting points. Herein, we demonstrate a direct crystal-to-glass transition in HKUST-1 MOF that has been achieved at room temperature and a relatively low pressure of <1.0 GPa. The dramatic fall in the required pressure is shown to arise from the aggregation of coordinated polar water molecules to form water clusters that exhibit a pulling effect on the Cu–O(ligand) bonds. Meanwhile, the departed fragment gets flipped unfavorably to prevent further regeneration of the bond. Accordingly, a grain boundary-free continuous porous framework in the glassy state is successfully formed and can be fabricated into membranes. Given their unique microporosity and grain boundary-free characteristics, such MOF glass membranes present new opportunities for chemical separation (both gases and liquids), electrochemistry, and catalysts, promising a new platform for MOF glasses. {\textcopyright} 2026 The Author(s). InfoMat published by UESTC and John Wiley \& Sons Australia, Ltd.",

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author = "Jianguo Sun and Kirk, \{Chin Ho\} and Yunchuan Pu and Palakkal, \{Athulya S.\} and Ting, \{Lewis Kien Juen\} and Fei Wang and Chong, \{Kok Chan\} and Tuo Wang and Mohamed, \{Saad Aldin\} and Bin Liu and Jianwen Jiang and Cheetham, \{Anthony K.\} and Dan Zhao and John Wang",

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TY - JOUR

T1 - Water cluster triggered vitrification in HKUST-1 MOF crystal under pressure

AU - Sun, Jianguo

AU - Kirk, Chin Ho

AU - Pu, Yunchuan

AU - Palakkal, Athulya S.

AU - Ting, Lewis Kien Juen

AU - Wang, Fei

AU - Chong, Kok Chan

AU - Wang, Tuo

AU - Mohamed, Saad Aldin

AU - Liu, Bin

AU - Jiang, Jianwen

AU - Cheetham, Anthony K.

AU - Zhao, Dan

AU - Wang, John

PY - 2026/3

Y1 - 2026/3

N2 - Metal–organic framework (MOF) glasses feature several unique dynamic and thermodynamic properties that differentiate them from their crystalline counterparts. However, the formation of MOF glasses usually requires the melt-quenching of molten MOFs from relatively high temperatures. In practice, this approach is quite limited because most MOFs decompose below their melting points. Herein, we demonstrate a direct crystal-to-glass transition in HKUST-1 MOF that has been achieved at room temperature and a relatively low pressure of <1.0 GPa. The dramatic fall in the required pressure is shown to arise from the aggregation of coordinated polar water molecules to form water clusters that exhibit a pulling effect on the Cu–O(ligand) bonds. Meanwhile, the departed fragment gets flipped unfavorably to prevent further regeneration of the bond. Accordingly, a grain boundary-free continuous porous framework in the glassy state is successfully formed and can be fabricated into membranes. Given their unique microporosity and grain boundary-free characteristics, such MOF glass membranes present new opportunities for chemical separation (both gases and liquids), electrochemistry, and catalysts, promising a new platform for MOF glasses. © 2026 The Author(s). InfoMat published by UESTC and John Wiley & Sons Australia, Ltd.

AB - Metal–organic framework (MOF) glasses feature several unique dynamic and thermodynamic properties that differentiate them from their crystalline counterparts. However, the formation of MOF glasses usually requires the melt-quenching of molten MOFs from relatively high temperatures. In practice, this approach is quite limited because most MOFs decompose below their melting points. Herein, we demonstrate a direct crystal-to-glass transition in HKUST-1 MOF that has been achieved at room temperature and a relatively low pressure of <1.0 GPa. The dramatic fall in the required pressure is shown to arise from the aggregation of coordinated polar water molecules to form water clusters that exhibit a pulling effect on the Cu–O(ligand) bonds. Meanwhile, the departed fragment gets flipped unfavorably to prevent further regeneration of the bond. Accordingly, a grain boundary-free continuous porous framework in the glassy state is successfully formed and can be fabricated into membranes. Given their unique microporosity and grain boundary-free characteristics, such MOF glass membranes present new opportunities for chemical separation (both gases and liquids), electrochemistry, and catalysts, promising a new platform for MOF glasses. © 2026 The Author(s). InfoMat published by UESTC and John Wiley & Sons Australia, Ltd.

KW - grain-boundary-free membrane

KW - MOF glass

KW - molecular separation

KW - pressure-induced glass transition

KW - water cluster

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UR - https://www.scopus.com/record/pubmetrics.uri?eid=2-s2.0-105027665816&origin=recordpage

U2 - 10.1002/inf2.70100

DO - 10.1002/inf2.70100

M3 - RGC 21 - Publication in refereed journal

SN - 2567-3165

VL - 8

JO - InfoMat

JF - InfoMat

IS - 3

M1 - e70100

ER -

Water cluster triggered vitrification in HKUST-1 MOF crystal under pressure

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Research Keywords

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