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

16 Scopus citations

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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