Structural and Thermodynamic Understandings in Mn-Based Sodium Layered Oxides during Anionic Redox

Seok Mun Kang; Duho Kim; Kug Seung Lee; Min Seob Kim; Aihua Jin; Jae Hyuk Park; Chi Yeong Ahn; Tae Yeol Jeon; Young Hwa Jung; Seung Ho Yu; Junyoung Mun; Yung Eun Sung

doi:10.1002/advs.202001263

Structural and Thermodynamic Understandings in Mn-Based Sodium Layered Oxides during Anionic Redox

Seok Mun Kang
, Duho Kim
, Kug Seung Lee
, Min Seob Kim
, Aihua Jin
, Jae Hyuk Park
, Chi Yeong Ahn
, Tae Yeol Jeon
, Young Hwa Jung
, Seung Ho Yu
, Junyoung Mun
, Yung Eun Sung

Institute for Basic Science
Seoul National University
Kyung Hee University
Pohang University of Science and Technology
Korea University
Incheon National University

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

57 Scopus citations

Abstract

A breakthrough utilizing an anionic redox reaction (O²⁻/Oⁿ⁻) for charge compensation has led to the development of high-energy cathode materials in sodium-ion batteries. However, its reaction results in a large voltage hysteresis due to the structural degradation arising from an oxygen loss. Herein, an interesting P2-type Mn-based compound exhibits a distinct two-phase behavior preserving a high-potential anionic redox (≈4.2 V vs Na⁺/Na) even during the subsequent cycling. Through a systematic series of experimental characterizations and theoretical calculations, the anionic redox reaction originating from O 2p-electron and the reversible unmixing of Na-rich and Na-poor phases are confirmed in detail. In light of the combined study, a critical role of the anion-redox-induced two-phase reaction in the positive-negative point of view is demonstrated, suggesting a rational design principle considering the phase separation and lattice mismatch. Furthermore, these results provide an exciting approach for utilizing the high-voltage feature in Mn-based layered cathode materials that are charge-compensated by an anionic redox reaction.

Original language	English
Article number	2001263
Journal	Advanced Science
Volume	7
Issue number	16
DOIs	https://doi.org/10.1002/advs.202001263
State	Published - 1 Aug 2020
Externally published	Yes

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Keywords

anionic redox
cathodes
sodium ion batteries
two-phase reactions

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10.1002/advs.202001263

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title = "Structural and Thermodynamic Understandings in Mn-Based Sodium Layered Oxides during Anionic Redox",

abstract = "A breakthrough utilizing an anionic redox reaction (O2−/On−) for charge compensation has led to the development of high-energy cathode materials in sodium-ion batteries. However, its reaction results in a large voltage hysteresis due to the structural degradation arising from an oxygen loss. Herein, an interesting P2-type Mn-based compound exhibits a distinct two-phase behavior preserving a high-potential anionic redox (≈4.2 V vs Na+/Na) even during the subsequent cycling. Through a systematic series of experimental characterizations and theoretical calculations, the anionic redox reaction originating from O 2p-electron and the reversible unmixing of Na-rich and Na-poor phases are confirmed in detail. In light of the combined study, a critical role of the anion-redox-induced two-phase reaction in the positive-negative point of view is demonstrated, suggesting a rational design principle considering the phase separation and lattice mismatch. Furthermore, these results provide an exciting approach for utilizing the high-voltage feature in Mn-based layered cathode materials that are charge-compensated by an anionic redox reaction.",

keywords = "anionic redox, cathodes, sodium ion batteries, two-phase reactions",

author = "Kang, \{Seok Mun\} and Duho Kim and Lee, \{Kug Seung\} and Kim, \{Min Seob\} and Aihua Jin and Park, \{Jae Hyuk\} and Ahn, \{Chi Yeong\} and Jeon, \{Tae Yeol\} and Jung, \{Young Hwa\} and Yu, \{Seung Ho\} and Junyoung Mun and Sung, \{Yung Eun\}",

note = "Publisher Copyright: {\textcopyright} 2020 The Authors. Published by WILEY-VCH Verlag GmbH \& Co. KGaA, Weinheim",

year = "2020",

month = aug,

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doi = "10.1002/advs.202001263",

language = "English",

volume = "7",

journal = "Advanced Science",

issn = "2198-3844",

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TY - JOUR

T1 - Structural and Thermodynamic Understandings in Mn-Based Sodium Layered Oxides during Anionic Redox

AU - Kang, Seok Mun

AU - Kim, Duho

AU - Lee, Kug Seung

AU - Kim, Min Seob

AU - Jin, Aihua

AU - Park, Jae Hyuk

AU - Ahn, Chi Yeong

AU - Jeon, Tae Yeol

AU - Jung, Young Hwa

AU - Yu, Seung Ho

AU - Mun, Junyoung

AU - Sung, Yung Eun

PY - 2020/8/1

Y1 - 2020/8/1

N2 - A breakthrough utilizing an anionic redox reaction (O2−/On−) for charge compensation has led to the development of high-energy cathode materials in sodium-ion batteries. However, its reaction results in a large voltage hysteresis due to the structural degradation arising from an oxygen loss. Herein, an interesting P2-type Mn-based compound exhibits a distinct two-phase behavior preserving a high-potential anionic redox (≈4.2 V vs Na+/Na) even during the subsequent cycling. Through a systematic series of experimental characterizations and theoretical calculations, the anionic redox reaction originating from O 2p-electron and the reversible unmixing of Na-rich and Na-poor phases are confirmed in detail. In light of the combined study, a critical role of the anion-redox-induced two-phase reaction in the positive-negative point of view is demonstrated, suggesting a rational design principle considering the phase separation and lattice mismatch. Furthermore, these results provide an exciting approach for utilizing the high-voltage feature in Mn-based layered cathode materials that are charge-compensated by an anionic redox reaction.

AB - A breakthrough utilizing an anionic redox reaction (O2−/On−) for charge compensation has led to the development of high-energy cathode materials in sodium-ion batteries. However, its reaction results in a large voltage hysteresis due to the structural degradation arising from an oxygen loss. Herein, an interesting P2-type Mn-based compound exhibits a distinct two-phase behavior preserving a high-potential anionic redox (≈4.2 V vs Na+/Na) even during the subsequent cycling. Through a systematic series of experimental characterizations and theoretical calculations, the anionic redox reaction originating from O 2p-electron and the reversible unmixing of Na-rich and Na-poor phases are confirmed in detail. In light of the combined study, a critical role of the anion-redox-induced two-phase reaction in the positive-negative point of view is demonstrated, suggesting a rational design principle considering the phase separation and lattice mismatch. Furthermore, these results provide an exciting approach for utilizing the high-voltage feature in Mn-based layered cathode materials that are charge-compensated by an anionic redox reaction.

KW - anionic redox

KW - cathodes

KW - sodium ion batteries

KW - two-phase reactions

UR - https://www.scopus.com/pages/publications/85087307574

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DO - 10.1002/advs.202001263

M3 - Article

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SN - 2198-3844

VL - 7

JO - Advanced Science

JF - Advanced Science

IS - 16

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ER -

Structural and Thermodynamic Understandings in Mn-Based Sodium Layered Oxides during Anionic Redox

Abstract

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Keywords

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