Unraveling the Charge Storage Mechanism of β-MnO2 in Aqueous Zinc Electrolytes

Lang Yuan Wu; Zhi Wei Li; Yu Xuan Xiang; Wen Di Dong; Hai Yang Wu; Ying Hong Xu; Zhen Xiao Ling; Munseok S. Chae; Daniel Sharon; Netanel Shpigel; Xiao Gang Zhang

doi:10.1021/acsenergylett.4c02559

Unraveling the Charge Storage Mechanism of β-MnO₂ in Aqueous Zinc Electrolytes

Lang Yuan Wu, Zhi Wei Li, Yu Xuan Xiang, Wen Di Dong, Hai Yang Wu, Ying Hong Xu, Zhen Xiao Ling, Munseok S. Chae, Daniel Sharon, Netanel Shpigel, Xiao Gang Zhang

Department of Chemical Sciences

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

Abstract

MnO₂-based zinc-ion batteries have emerged as a promising candidate for next-generation energy storage systems. Despite extensive research on MnO₂ electrodes, the charging mechanism in mildly acidic electrolytes remains debated. Most studies have focused on α-MnO₂, and this study aims to shed light on the identity of the charge carrier in β-MnO₂ and the role of the Mn²⁺ cations. By employing in situ EQCM-D measurements, along with ssNMR, XRD, TEM, and in situ pH monitoring, we demonstrated that the charging mechanism is primarily governed by proton de/intercalation. Compared to α-MnO₂, with its larger 2 × 2 tunnels that accommodate hydronium ions, the β-phase has smaller 1 × 1 tunnels, permitting only the insertion of bare protons. During cycling, we observed the formation of new phases on β-MnO₂ originating from the repetitive electrodeposition/dissolution of Mn²⁺.

Original language	English
Pages (from-to)	5801-5809
Number of pages	9
Journal	ACS Energy Letters
Volume	9
Issue number	12
DOIs	https://doi.org/10.1021/acsenergylett.4c02559
State	Published - 13 Dec 2024

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title = "Unraveling the Charge Storage Mechanism of β-MnO2 in Aqueous Zinc Electrolytes",

abstract = "MnO2-based zinc-ion batteries have emerged as a promising candidate for next-generation energy storage systems. Despite extensive research on MnO2 electrodes, the charging mechanism in mildly acidic electrolytes remains debated. Most studies have focused on α-MnO2, and this study aims to shed light on the identity of the charge carrier in β-MnO2 and the role of the Mn2+ cations. By employing in situ EQCM-D measurements, along with ssNMR, XRD, TEM, and in situ pH monitoring, we demonstrated that the charging mechanism is primarily governed by proton de/intercalation. Compared to α-MnO2, with its larger 2 × 2 tunnels that accommodate hydronium ions, the β-phase has smaller 1 × 1 tunnels, permitting only the insertion of bare protons. During cycling, we observed the formation of new phases on β-MnO2 originating from the repetitive electrodeposition/dissolution of Mn2+.",

author = "Wu, {Lang Yuan} and Li, {Zhi Wei} and Xiang, {Yu Xuan} and Dong, {Wen Di} and Wu, {Hai Yang} and Xu, {Ying Hong} and Ling, {Zhen Xiao} and Chae, {Munseok S.} and Daniel Sharon and Netanel Shpigel and Zhang, {Xiao Gang}",

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doi = "10.1021/acsenergylett.4c02559",

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AU - Wu, Lang Yuan

AU - Li, Zhi Wei

AU - Xiang, Yu Xuan

AU - Dong, Wen Di

AU - Wu, Hai Yang

AU - Xu, Ying Hong

AU - Ling, Zhen Xiao

AU - Chae, Munseok S.

AU - Sharon, Daniel

AU - Shpigel, Netanel

AU - Zhang, Xiao Gang

PY - 2024/12/13

Y1 - 2024/12/13

N2 - MnO2-based zinc-ion batteries have emerged as a promising candidate for next-generation energy storage systems. Despite extensive research on MnO2 electrodes, the charging mechanism in mildly acidic electrolytes remains debated. Most studies have focused on α-MnO2, and this study aims to shed light on the identity of the charge carrier in β-MnO2 and the role of the Mn2+ cations. By employing in situ EQCM-D measurements, along with ssNMR, XRD, TEM, and in situ pH monitoring, we demonstrated that the charging mechanism is primarily governed by proton de/intercalation. Compared to α-MnO2, with its larger 2 × 2 tunnels that accommodate hydronium ions, the β-phase has smaller 1 × 1 tunnels, permitting only the insertion of bare protons. During cycling, we observed the formation of new phases on β-MnO2 originating from the repetitive electrodeposition/dissolution of Mn2+.

AB - MnO2-based zinc-ion batteries have emerged as a promising candidate for next-generation energy storage systems. Despite extensive research on MnO2 electrodes, the charging mechanism in mildly acidic electrolytes remains debated. Most studies have focused on α-MnO2, and this study aims to shed light on the identity of the charge carrier in β-MnO2 and the role of the Mn2+ cations. By employing in situ EQCM-D measurements, along with ssNMR, XRD, TEM, and in situ pH monitoring, we demonstrated that the charging mechanism is primarily governed by proton de/intercalation. Compared to α-MnO2, with its larger 2 × 2 tunnels that accommodate hydronium ions, the β-phase has smaller 1 × 1 tunnels, permitting only the insertion of bare protons. During cycling, we observed the formation of new phases on β-MnO2 originating from the repetitive electrodeposition/dissolution of Mn2+.

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Unraveling the Charge Storage Mechanism of β-MnO₂ in Aqueous Zinc Electrolytes

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