Carboxyl-CNTs Act as “Defensive Shield” to Boost Proton Insertion for Stable and Fast-Charging Aqueous Zn-Mn Batteries

Yanchen Fan; Meng Xu; Qi Li; Mengyao Liu; Xiaoru Zhang; Pan Chu; Biao Zhang; Hongyu Zhou; Yi Zhao; Chenguang Liu

doi:10.1002/smll.202501454

Carboxyl-CNTs Act as “Defensive Shield” to Boost Proton Insertion for Stable and Fast-Charging Aqueous Zn-Mn Batteries

Yanchen Fan, Meng Xu, Qi Li, Mengyao Liu, Xiaoru Zhang, Pan Chu, Biao Zhang, Hongyu Zhou, Yi Zhao^*, Chenguang Liu^*

^*Corresponding author for this work

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

Abstract

Proton insertion mechanism with fast reaction kinetics is attracting more and more attention for high-rate and durable aqueous Zn─MnO₂ batteries. However, hydrated Zn²⁺ insertion reaction accompanied with Jahn–Teller effect and Mn³⁺ disproportionation generally leads to sluggish rate capability and irreversible structure transformation. Here, carboxyl-carbon nanotubes supported α-MnO₂ nanoarrays (C─MnO₂) cathode is successfully fabricated by a convent grinding process for high-performance Zn batteries. Specifically, the carboxyl-carbon nanotubes (CNTs) skeleton endows α-MnO₂ with a shorter ion diffusion route and more active sites for proton adsorption, benefiting to the fast electron transport and reversible structure evolution of MnO₂. More importantly, electronegative carboxyl groups and Mn─O─C interfacial bonds can effectively restrain Mn²⁺ dissolution and shuttle for improved structural integrity and redox reactivity. Consequently, the C─MnO₂ cathode exhibits high capacity, superior rate capability, and outstanding cycling stability over 10 000 cycles. Even at ultra-high mass loading (20 mg cm⁻²), the Zn//C─MnO₂ punch cell displays excellent capacity (202 mAh) and 94.5% capacity retention after 114 cycles, providing new insights for the practical application of advanced Zn-Mn batteries.

Original language	English
Journal	Small
DOIs	https://doi.org/10.1002/smll.202501454
Publication status	Accepted/In press - 2025
Externally published	Yes

Keywords

aqueous Zn-Mn battery
carboxyl-CNTs
high performance
interfacial optimization
proton insertion

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10.1002/smll.202501454

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Fan, Y., Xu, M., Li, Q., Liu, M., Zhang, X., Chu, P., Zhang, B., Zhou, H., Zhao, Y., & Liu, C. (Accepted/In press). Carboxyl-CNTs Act as “Defensive Shield” to Boost Proton Insertion for Stable and Fast-Charging Aqueous Zn-Mn Batteries. Small. https://doi.org/10.1002/smll.202501454

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title = "Carboxyl-CNTs Act as “Defensive Shield” to Boost Proton Insertion for Stable and Fast-Charging Aqueous Zn-Mn Batteries",

abstract = "Proton insertion mechanism with fast reaction kinetics is attracting more and more attention for high-rate and durable aqueous Zn─MnO2 batteries. However, hydrated Zn2+ insertion reaction accompanied with Jahn–Teller effect and Mn3+ disproportionation generally leads to sluggish rate capability and irreversible structure transformation. Here, carboxyl-carbon nanotubes supported α-MnO2 nanoarrays (C─MnO2) cathode is successfully fabricated by a convent grinding process for high-performance Zn batteries. Specifically, the carboxyl-carbon nanotubes (CNTs) skeleton endows α-MnO2 with a shorter ion diffusion route and more active sites for proton adsorption, benefiting to the fast electron transport and reversible structure evolution of MnO2. More importantly, electronegative carboxyl groups and Mn─O─C interfacial bonds can effectively restrain Mn2+ dissolution and shuttle for improved structural integrity and redox reactivity. Consequently, the C─MnO2 cathode exhibits high capacity, superior rate capability, and outstanding cycling stability over 10 000 cycles. Even at ultra-high mass loading (20 mg cm−2), the Zn//C─MnO2 punch cell displays excellent capacity (202 mAh) and 94.5% capacity retention after 114 cycles, providing new insights for the practical application of advanced Zn-Mn batteries.",

keywords = "aqueous Zn-Mn battery, carboxyl-CNTs, high performance, interfacial optimization, proton insertion",

author = "Yanchen Fan and Meng Xu and Qi Li and Mengyao Liu and Xiaoru Zhang and Pan Chu and Biao Zhang and Hongyu Zhou and Yi Zhao and Chenguang Liu",

note = "Publisher Copyright: {\textcopyright} 2025 Wiley-VCH GmbH.",

year = "2025",

doi = "10.1002/smll.202501454",

language = "English",

journal = "Small",

issn = "1613-6810",

publisher = "Wiley-VCH Verlag",

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TY - JOUR

T1 - Carboxyl-CNTs Act as “Defensive Shield” to Boost Proton Insertion for Stable and Fast-Charging Aqueous Zn-Mn Batteries

AU - Fan, Yanchen

AU - Xu, Meng

AU - Li, Qi

AU - Liu, Mengyao

AU - Zhang, Xiaoru

AU - Chu, Pan

AU - Zhang, Biao

AU - Zhou, Hongyu

AU - Zhao, Yi

AU - Liu, Chenguang

PY - 2025

Y1 - 2025

N2 - Proton insertion mechanism with fast reaction kinetics is attracting more and more attention for high-rate and durable aqueous Zn─MnO2 batteries. However, hydrated Zn2+ insertion reaction accompanied with Jahn–Teller effect and Mn3+ disproportionation generally leads to sluggish rate capability and irreversible structure transformation. Here, carboxyl-carbon nanotubes supported α-MnO2 nanoarrays (C─MnO2) cathode is successfully fabricated by a convent grinding process for high-performance Zn batteries. Specifically, the carboxyl-carbon nanotubes (CNTs) skeleton endows α-MnO2 with a shorter ion diffusion route and more active sites for proton adsorption, benefiting to the fast electron transport and reversible structure evolution of MnO2. More importantly, electronegative carboxyl groups and Mn─O─C interfacial bonds can effectively restrain Mn2+ dissolution and shuttle for improved structural integrity and redox reactivity. Consequently, the C─MnO2 cathode exhibits high capacity, superior rate capability, and outstanding cycling stability over 10 000 cycles. Even at ultra-high mass loading (20 mg cm−2), the Zn//C─MnO2 punch cell displays excellent capacity (202 mAh) and 94.5% capacity retention after 114 cycles, providing new insights for the practical application of advanced Zn-Mn batteries.

AB - Proton insertion mechanism with fast reaction kinetics is attracting more and more attention for high-rate and durable aqueous Zn─MnO2 batteries. However, hydrated Zn2+ insertion reaction accompanied with Jahn–Teller effect and Mn3+ disproportionation generally leads to sluggish rate capability and irreversible structure transformation. Here, carboxyl-carbon nanotubes supported α-MnO2 nanoarrays (C─MnO2) cathode is successfully fabricated by a convent grinding process for high-performance Zn batteries. Specifically, the carboxyl-carbon nanotubes (CNTs) skeleton endows α-MnO2 with a shorter ion diffusion route and more active sites for proton adsorption, benefiting to the fast electron transport and reversible structure evolution of MnO2. More importantly, electronegative carboxyl groups and Mn─O─C interfacial bonds can effectively restrain Mn2+ dissolution and shuttle for improved structural integrity and redox reactivity. Consequently, the C─MnO2 cathode exhibits high capacity, superior rate capability, and outstanding cycling stability over 10 000 cycles. Even at ultra-high mass loading (20 mg cm−2), the Zn//C─MnO2 punch cell displays excellent capacity (202 mAh) and 94.5% capacity retention after 114 cycles, providing new insights for the practical application of advanced Zn-Mn batteries.

KW - aqueous Zn-Mn battery

KW - carboxyl-CNTs

KW - high performance

KW - interfacial optimization

KW - proton insertion

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U2 - 10.1002/smll.202501454

DO - 10.1002/smll.202501454

M3 - Article

AN - SCOPUS:105000370086

SN - 1613-6810

JO - Small

JF - Small

ER -

Carboxyl-CNTs Act as “Defensive Shield” to Boost Proton Insertion for Stable and Fast-Charging Aqueous Zn-Mn Batteries

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