Water-Enhanced Multicolor Electrochromism in Nickel-Catecholate MOFs

Qi Zhao; Jing Yang; Xingyang Wang; Wanwan Wang; Yulin Gao; Xue Chen; Jianguo Sun; Hao Yuan; Yu Liu; Jinwoo Park; Lewis Kien Juen Ting; Qing Wang; Pooi See Lee; Yanfeng Gao; Yong Wei Zhang; John Wang

doi:10.1002/advs.202500678

Water-Enhanced Multicolor Electrochromism in Nickel-Catecholate MOFs

Qi Zhao, Jing Yang, Xingyang Wang, Wanwan Wang, Yulin Gao, Xue Chen, Jianguo Sun, Hao Yuan, Yu Liu^*, Jinwoo Park, Lewis Kien Juen Ting, Qing Wang, Pooi See Lee, Yanfeng Gao^*, Yong Wei Zhang^*, John Wang^*

^*Corresponding author for this work

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

Abstract

Metal–organic frameworks (MOFs) represent a novel electrochromic material system but are limited in tunable color versatility, rapid switching speed, and long-term cycling stability. A new multicolor electrochromic behavior is reported, with transitions from green to blue to purple, in conducting nickel-catecholate (Ni-CAT-1) MOFs. The system significantly improves cycling stability to 2000 cycles and reduces switching time to 3.6 s, both of which outperform most state-of-the-art MOF systems. An in-depth understanding of the coloring mechanism, particularly the interconversion among C─O, C─O^•, and C = O groups is revealed. Water molecules play diverse roles in this redox process. Specifically, water molecules induce distortions in Ni─O bonds, facilitating C = O bond formation and expediting the oxidized coloring process, while also aiding the dissociation of ions from solvation complexes to enhance the reduction process. The practical applications of these findings are demonstrated by designing flexible multicolor electrochromic devices (FMEDs) for use in camouflage, flexible displays, and augmented reality (AR).

Original language	English
Journal	Advanced Science
DOIs	https://doi.org/10.1002/advs.202500678
Publication status	Accepted/In press - 2025
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2025 The Author(s). Advanced Science published by Wiley-VCH GmbH.

ASJC Scopus Subject Areas

Medicine (miscellaneous)
General Chemical Engineering
General Materials Science
Biochemistry, Genetics and Molecular Biology (miscellaneous)
General Engineering
General Physics and Astronomy

Keywords

coloring mechanism
conducting metal–organic frameworks
multicolor electrochromic behavior
water molecules

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10.1002/advs.202500678

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title = "Water-Enhanced Multicolor Electrochromism in Nickel-Catecholate MOFs",

abstract = "Metal–organic frameworks (MOFs) represent a novel electrochromic material system but are limited in tunable color versatility, rapid switching speed, and long-term cycling stability. A new multicolor electrochromic behavior is reported, with transitions from green to blue to purple, in conducting nickel-catecholate (Ni-CAT-1) MOFs. The system significantly improves cycling stability to 2000 cycles and reduces switching time to 3.6 s, both of which outperform most state-of-the-art MOF systems. An in-depth understanding of the coloring mechanism, particularly the interconversion among C─O, C─O•, and C = O groups is revealed. Water molecules play diverse roles in this redox process. Specifically, water molecules induce distortions in Ni─O bonds, facilitating C = O bond formation and expediting the oxidized coloring process, while also aiding the dissociation of ions from solvation complexes to enhance the reduction process. The practical applications of these findings are demonstrated by designing flexible multicolor electrochromic devices (FMEDs) for use in camouflage, flexible displays, and augmented reality (AR).",

keywords = "coloring mechanism, conducting metal–organic frameworks, multicolor electrochromic behavior, water molecules",

author = "Qi Zhao and Jing Yang and Xingyang Wang and Wanwan Wang and Yulin Gao and Xue Chen and Jianguo Sun and Hao Yuan and Yu Liu and Jinwoo Park and Ting, {Lewis Kien Juen} and Qing Wang and Lee, {Pooi See} and Yanfeng Gao and Zhang, {Yong Wei} and John Wang",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Advanced Science published by Wiley-VCH GmbH.",

year = "2025",

doi = "10.1002/advs.202500678",

language = "English",

journal = "Advanced Science",

issn = "2198-3844",

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TY - JOUR

T1 - Water-Enhanced Multicolor Electrochromism in Nickel-Catecholate MOFs

AU - Zhao, Qi

AU - Yang, Jing

AU - Wang, Xingyang

AU - Wang, Wanwan

AU - Gao, Yulin

AU - Chen, Xue

AU - Sun, Jianguo

AU - Yuan, Hao

AU - Liu, Yu

AU - Park, Jinwoo

AU - Ting, Lewis Kien Juen

AU - Wang, Qing

AU - Lee, Pooi See

AU - Gao, Yanfeng

AU - Zhang, Yong Wei

AU - Wang, John

PY - 2025

Y1 - 2025

N2 - Metal–organic frameworks (MOFs) represent a novel electrochromic material system but are limited in tunable color versatility, rapid switching speed, and long-term cycling stability. A new multicolor electrochromic behavior is reported, with transitions from green to blue to purple, in conducting nickel-catecholate (Ni-CAT-1) MOFs. The system significantly improves cycling stability to 2000 cycles and reduces switching time to 3.6 s, both of which outperform most state-of-the-art MOF systems. An in-depth understanding of the coloring mechanism, particularly the interconversion among C─O, C─O•, and C = O groups is revealed. Water molecules play diverse roles in this redox process. Specifically, water molecules induce distortions in Ni─O bonds, facilitating C = O bond formation and expediting the oxidized coloring process, while also aiding the dissociation of ions from solvation complexes to enhance the reduction process. The practical applications of these findings are demonstrated by designing flexible multicolor electrochromic devices (FMEDs) for use in camouflage, flexible displays, and augmented reality (AR).

AB - Metal–organic frameworks (MOFs) represent a novel electrochromic material system but are limited in tunable color versatility, rapid switching speed, and long-term cycling stability. A new multicolor electrochromic behavior is reported, with transitions from green to blue to purple, in conducting nickel-catecholate (Ni-CAT-1) MOFs. The system significantly improves cycling stability to 2000 cycles and reduces switching time to 3.6 s, both of which outperform most state-of-the-art MOF systems. An in-depth understanding of the coloring mechanism, particularly the interconversion among C─O, C─O•, and C = O groups is revealed. Water molecules play diverse roles in this redox process. Specifically, water molecules induce distortions in Ni─O bonds, facilitating C = O bond formation and expediting the oxidized coloring process, while also aiding the dissociation of ions from solvation complexes to enhance the reduction process. The practical applications of these findings are demonstrated by designing flexible multicolor electrochromic devices (FMEDs) for use in camouflage, flexible displays, and augmented reality (AR).

KW - coloring mechanism

KW - conducting metal–organic frameworks

KW - multicolor electrochromic behavior

KW - water molecules

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SN - 2198-3844

JO - Advanced Science

JF - Advanced Science

ER -

Water-Enhanced Multicolor Electrochromism in Nickel-Catecholate MOFs

Abstract

Bibliographical note

ASJC Scopus Subject Areas

Keywords

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