Missing-Linker Defect Functionalized Metal−Organic Frameworks Accelerating Zinc Ion Conduction for Ultrastable All-Solid-State Zinc Metal Batteries

Xiaobin Hui; Zhen Zhan; Zeyu Zhang; Jingya Yu; Pengyan Jiang; Zhengzheng Dang; Jian Wang; Songhua Cai; Yanming Wang; Zheng-Long Xu

doi:10.1021/acsnano.4c07907

Missing-Linker Defect Functionalized Metal−Organic Frameworks Accelerating Zinc Ion Conduction for Ultrastable All-Solid-State Zinc Metal Batteries

Xiaobin Hui, Zhen Zhan, Zeyu Zhang, Jingya Yu, Pengyan Jiang, Zhengzheng Dang, Jian Wang, Songhua Cai^*, Yanming Wang^*, Zheng-Long Xu^*

^*Corresponding author for this work

School of Energy and Environment

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

24 Citations (Scopus)

Abstract

Solid-state polymer electrolytes (SPEs) are promising for high-performance zinc metal batteries (ZMBs), but they encounter critical challenges of low ionic conductivity, limited Zn²⁺ transference number (t_Zn2+), and an unstable electrolyte-electrode interface. Here, we present an effective approach involving a missing-linker metallic organic framework (MOF)-catalyzed poly(ethylene glycol) diacrylate (PEGDA)/polyacrylamide (PAM) copolymer SPE for single Zn²⁺ conduction and seamless electrolyte-electrode contact. The single-Zn²⁺ conduction is facilitated by the anchoring of the OTF^- anions onto the unsaturated metal sites of missing-linker MOF, while the PEGDA and PAM chains in competitive coordination with Zn²⁺ ions promote rapid Zn ion transport. Our all-solid-state electrolyte simultaneously achieves a superior ionic conductivity of 1.52 mS cm^-1 and a high t_Zn2+ of 0.83 at room temperature, alongside uniform Zn metal deposition (1000 cycles in symmetric cells) and high Zn plating/striping efficiencies (>99% after 600 cycles in asymmetric cells). Applications of our SPE in Zn//VO₂ full cells are further demonstrated with a long lifespan of 2000 cycles and an extremely low-capacity degradation rate of 0.012% per cycle. This work provides an effective strategy for using a missing-linker MOF to catalyze competitively coordinating copolymers for accelerating Zn²⁺ ion conduction, assisting the future design of all-solid-state ZMBs. © 2024 American Chemical Society.

Original language	English
Pages (from-to)	25237-25248
Journal	ACS Nano
Volume	18
Issue number	36
Online published	29 Aug 2024
DOIs	https://doi.org/10.1021/acsnano.4c07907
Publication status	Published - 10 Sept 2024

Funding

The work described in this paper was supported by funding supports from the Research Institute of Advanced Manufacturing (RIAM) and the State Key Laboratory of Ultraprecision Machining Technology (SKL-UPMT) of the Hong Kong Polytechnic University (project No. 1-CD4M, 1-BBR0) and the PolyU Distinguished Postdoctoral Fellowship Scheme (project No. 1-YWD8), Department of Science and Technology of Guangdong Province (Project No. 2022A1515010206). S.C. acknowledges the support of the startup grant from the Department of Applied Physics, the Hong Kong Polytechnic University (1-BDCM), and the Hong Kong Research Grants Council General Research Fund (No. 15306122).

Research Keywords

competitive coordination
defected MOF
single-ion conducting
solid-state electrolyte
Zn-ion battery

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title = "Missing-Linker Defect Functionalized Metal−Organic Frameworks Accelerating Zinc Ion Conduction for Ultrastable All-Solid-State Zinc Metal Batteries",

abstract = "Solid-state polymer electrolytes (SPEs) are promising for high-performance zinc metal batteries (ZMBs), but they encounter critical challenges of low ionic conductivity, limited Zn2+ transference number (tZn2+), and an unstable electrolyte-electrode interface. Here, we present an effective approach involving a missing-linker metallic organic framework (MOF)-catalyzed poly(ethylene glycol) diacrylate (PEGDA)/polyacrylamide (PAM) copolymer SPE for single Zn2+ conduction and seamless electrolyte-electrode contact. The single-Zn2+ conduction is facilitated by the anchoring of the OTF- anions onto the unsaturated metal sites of missing-linker MOF, while the PEGDA and PAM chains in competitive coordination with Zn2+ ions promote rapid Zn ion transport. Our all-solid-state electrolyte simultaneously achieves a superior ionic conductivity of 1.52 mS cm-1 and a high tZn2+ of 0.83 at room temperature, alongside uniform Zn metal deposition (1000 cycles in symmetric cells) and high Zn plating/striping efficiencies (>99% after 600 cycles in asymmetric cells). Applications of our SPE in Zn//VO2 full cells are further demonstrated with a long lifespan of 2000 cycles and an extremely low-capacity degradation rate of 0.012% per cycle. This work provides an effective strategy for using a missing-linker MOF to catalyze competitively coordinating copolymers for accelerating Zn2+ ion conduction, assisting the future design of all-solid-state ZMBs. {\textcopyright} 2024 American Chemical Society.",

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author = "Xiaobin Hui and Zhen Zhan and Zeyu Zhang and Jingya Yu and Pengyan Jiang and Zhengzheng Dang and Jian Wang and Songhua Cai and Yanming Wang and Zheng-Long Xu",

year = "2024",

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doi = "10.1021/acsnano.4c07907",

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T1 - Missing-Linker Defect Functionalized Metal−Organic Frameworks Accelerating Zinc Ion Conduction for Ultrastable All-Solid-State Zinc Metal Batteries

AU - Hui, Xiaobin

AU - Zhan, Zhen

AU - Zhang, Zeyu

AU - Yu, Jingya

AU - Jiang, Pengyan

AU - Dang, Zhengzheng

AU - Wang, Jian

AU - Cai, Songhua

AU - Wang, Yanming

AU - Xu, Zheng-Long

PY - 2024/9/10

Y1 - 2024/9/10

N2 - Solid-state polymer electrolytes (SPEs) are promising for high-performance zinc metal batteries (ZMBs), but they encounter critical challenges of low ionic conductivity, limited Zn2+ transference number (tZn2+), and an unstable electrolyte-electrode interface. Here, we present an effective approach involving a missing-linker metallic organic framework (MOF)-catalyzed poly(ethylene glycol) diacrylate (PEGDA)/polyacrylamide (PAM) copolymer SPE for single Zn2+ conduction and seamless electrolyte-electrode contact. The single-Zn2+ conduction is facilitated by the anchoring of the OTF- anions onto the unsaturated metal sites of missing-linker MOF, while the PEGDA and PAM chains in competitive coordination with Zn2+ ions promote rapid Zn ion transport. Our all-solid-state electrolyte simultaneously achieves a superior ionic conductivity of 1.52 mS cm-1 and a high tZn2+ of 0.83 at room temperature, alongside uniform Zn metal deposition (1000 cycles in symmetric cells) and high Zn plating/striping efficiencies (>99% after 600 cycles in asymmetric cells). Applications of our SPE in Zn//VO2 full cells are further demonstrated with a long lifespan of 2000 cycles and an extremely low-capacity degradation rate of 0.012% per cycle. This work provides an effective strategy for using a missing-linker MOF to catalyze competitively coordinating copolymers for accelerating Zn2+ ion conduction, assisting the future design of all-solid-state ZMBs. © 2024 American Chemical Society.

AB - Solid-state polymer electrolytes (SPEs) are promising for high-performance zinc metal batteries (ZMBs), but they encounter critical challenges of low ionic conductivity, limited Zn2+ transference number (tZn2+), and an unstable electrolyte-electrode interface. Here, we present an effective approach involving a missing-linker metallic organic framework (MOF)-catalyzed poly(ethylene glycol) diacrylate (PEGDA)/polyacrylamide (PAM) copolymer SPE for single Zn2+ conduction and seamless electrolyte-electrode contact. The single-Zn2+ conduction is facilitated by the anchoring of the OTF- anions onto the unsaturated metal sites of missing-linker MOF, while the PEGDA and PAM chains in competitive coordination with Zn2+ ions promote rapid Zn ion transport. Our all-solid-state electrolyte simultaneously achieves a superior ionic conductivity of 1.52 mS cm-1 and a high tZn2+ of 0.83 at room temperature, alongside uniform Zn metal deposition (1000 cycles in symmetric cells) and high Zn plating/striping efficiencies (>99% after 600 cycles in asymmetric cells). Applications of our SPE in Zn//VO2 full cells are further demonstrated with a long lifespan of 2000 cycles and an extremely low-capacity degradation rate of 0.012% per cycle. This work provides an effective strategy for using a missing-linker MOF to catalyze competitively coordinating copolymers for accelerating Zn2+ ion conduction, assisting the future design of all-solid-state ZMBs. © 2024 American Chemical Society.

KW - competitive coordination

KW - defected MOF

KW - single-ion conducting

KW - solid-state electrolyte

KW - Zn-ion battery

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DO - 10.1021/acsnano.4c07907

M3 - RGC 21 - Publication in refereed journal

SN - 1936-0851

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EP - 25248

JO - ACS Nano

JF - ACS Nano

IS - 36

ER -

Missing-Linker Defect Functionalized Metal−Organic Frameworks Accelerating Zinc Ion Conduction for Ultrastable All-Solid-State Zinc Metal Batteries

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Research Keywords

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