Unveiling Interstitial Anionic Electron-Driven Ultrahigh K-Ion Storage Capacity in a Novel Two-Dimensional Electride Exemplified by Sc3Si2

Yuanzheng Chen; Haifei Qin; Jun Zhou; Tong Yang; Bai Sun; Yuxiang Ni; Hongyan Wang; Simon A.T. Redfern; Maosheng Miao; Hai Qing Lin; Yuan Ping Feng

doi:10.1021/acs.jpclett.2c01888

Unveiling Interstitial Anionic Electron-Driven Ultrahigh K-Ion Storage Capacity in a Novel Two-Dimensional Electride Exemplified by Sc₃Si₂

Yuanzheng Chen^*, Haifei Qin, Jun Zhou, Tong Yang, Bai Sun, Yuxiang Ni, Hongyan Wang, Simon A.T. Redfern^*, Maosheng Miao, Hai Qing Lin, Yuan Ping Feng^*

^*Corresponding author for this work

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

22 Citations (Scopus)

Abstract

Two-dimensional (2D) electrides, characterized by excess interstitial anionic electron (IAE) in a crystalline 2D material, offer promising opportunities for the development of electrode materials, in particular in rechargeable metal-ion batteries applications. Although a few such potential electride materials have been reported, they generally show low metal-ion storage capacity, and the effect of IAE on the ion storage performance remains elusive so far. Here we report a novel 2D electride, [Sc3Si2]1+·1e-, with fascinating IAE-driven high alkali metal-ion storage capacity. In particular, its K-ion specific capacity can reach up to 1497 mA h g-1, higher than any previously reported 2D materials-based anodes in K-ion batteries (PIBs). The IAE in the [Sc3Si2]1+·1e- crystal accounts for such high capacity behavior, which can drift away and balance the charge on the metal-cation, playing a crucial role in stabilizing the metal-ion adsorption and enhancing multilayer-ions adsorption. This proposed IAE-driven storage mechanism provides an unprecedented avenue for the future design of high storage capacity electrode materials.

Original language	English
Pages (from-to)	7439-7447
Number of pages	9
Journal	Journal of Physical Chemistry Letters
Volume	13
Issue number	32
DOIs	https://doi.org/10.1021/acs.jpclett.2c01888
Publication status	Published - Aug 18 2022
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2022 American Chemical Society.

ASJC Scopus Subject Areas

General Materials Science
Physical and Theoretical Chemistry

Access to Document

10.1021/acs.jpclett.2c01888

Cite this

Chen, Y., Qin, H., Zhou, J., Yang, T., Sun, B., Ni, Y., Wang, H., Redfern, S. A. T., Miao, M., Lin, H. Q., & Feng, Y. P. (2022). Unveiling Interstitial Anionic Electron-Driven Ultrahigh K-Ion Storage Capacity in a Novel Two-Dimensional Electride Exemplified by Sc₃Si₂. Journal of Physical Chemistry Letters, 13(32), 7439-7447. https://doi.org/10.1021/acs.jpclett.2c01888

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title = "Unveiling Interstitial Anionic Electron-Driven Ultrahigh K-Ion Storage Capacity in a Novel Two-Dimensional Electride Exemplified by Sc3Si2",

abstract = "Two-dimensional (2D) electrides, characterized by excess interstitial anionic electron (IAE) in a crystalline 2D material, offer promising opportunities for the development of electrode materials, in particular in rechargeable metal-ion batteries applications. Although a few such potential electride materials have been reported, they generally show low metal-ion storage capacity, and the effect of IAE on the ion storage performance remains elusive so far. Here we report a novel 2D electride, [Sc3Si2]1+·1e-, with fascinating IAE-driven high alkali metal-ion storage capacity. In particular, its K-ion specific capacity can reach up to 1497 mA h g-1, higher than any previously reported 2D materials-based anodes in K-ion batteries (PIBs). The IAE in the [Sc3Si2]1+·1e- crystal accounts for such high capacity behavior, which can drift away and balance the charge on the metal-cation, playing a crucial role in stabilizing the metal-ion adsorption and enhancing multilayer-ions adsorption. This proposed IAE-driven storage mechanism provides an unprecedented avenue for the future design of high storage capacity electrode materials.",

author = "Yuanzheng Chen and Haifei Qin and Jun Zhou and Tong Yang and Bai Sun and Yuxiang Ni and Hongyan Wang and Redfern, {Simon A.T.} and Maosheng Miao and Lin, {Hai Qing} and Feng, {Yuan Ping}",

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AU - Yang, Tong

AU - Sun, Bai

AU - Ni, Yuxiang

AU - Wang, Hongyan

AU - Redfern, Simon A.T.

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AU - Lin, Hai Qing

AU - Feng, Yuan Ping

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