Local Redox Reaction of High Valence Manganese in Li2MnO3-Based Lithium Battery Cathodes

Local Redox Reaction of High Valence Manganese in Li2MnO3-Based Lithium Battery Cathodes

Summary: Li2MnO3 endows Li-rich layered oxides with a superior energy density; however, its electron transfer mechanism is still unclear. Here, the electronic and thermodynamic behavior of LixMnO3 (x = 0.5–2) is determined using first-principles computations. The cationic redox, anionic redox, and l...

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Main Authors: Zihe Zhang, Shu Zhao, Boya Wang, Haijun Yu
Format: Article
Language:English
Published: Elsevier 2020-05-01
Series:Cell Reports Physical Science
Subjects:
Li-rich layered oxides
local redox reaction
first-principles computation
Li-ion battery
Online Access:http://www.sciencedirect.com/science/article/pii/S2666386420300552
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spelling doaj-3c3cb5c0e43d4f03b01042bd60ff51892020-11-25T04:07:46ZengElsevierCell Reports Physical Science2666-38642020-05-0115100061Local Redox Reaction of High Valence Manganese in Li2MnO3-Based Lithium Battery CathodesZihe Zhang0Shu Zhao1Boya Wang2Haijun Yu3College of Materials Science & Engineering, Key Laboratory of Advanced Functional Materials, Ministry of Education, Beijing University of Technology, Beijing 100124, ChinaCollege of Materials Science & Engineering, Key Laboratory of Advanced Functional Materials, Ministry of Education, Beijing University of Technology, Beijing 100124, ChinaCollege of Materials Science & Engineering, Key Laboratory of Advanced Functional Materials, Ministry of Education, Beijing University of Technology, Beijing 100124, ChinaCollege of Materials Science & Engineering, Key Laboratory of Advanced Functional Materials, Ministry of Education, Beijing University of Technology, Beijing 100124, China; Corresponding authorSummary: Li2MnO3 endows Li-rich layered oxides with a superior energy density; however, its electron transfer mechanism is still unclear. Here, the electronic and thermodynamic behavior of LixMnO3 (x = 0.5–2) is determined using first-principles computations. The cationic redox, anionic redox, and local electron exchange in Mn-O polyhedron are revealed. An obvious electron donation inclination of manganese is demonstrated when the Li+ content is low. Through ab initio molecular dynamics, high valence Mn6+ and Mn7+ are generated in the form of MnO4 tetrahedrons with structural transformation toward a disordered structure, controlled by the Li+ content and dynamic energy barrier. Furthermore, a local redox reaction between Mn6+ or Mn7+ and their surrounding oxygen atoms is elucidated. Consequently, a comprehensive understanding regarding the electron transfer in LixMnO3 is provided. Our results bring insight regarding the electron transfer mechanism in Li-rich layered oxide cathode materials and encourage further reconsideration and investigation into its redox mechanism.http://www.sciencedirect.com/science/article/pii/S2666386420300552Li-rich layered oxideslocal redox reactionfirst-principles computationLi-ion battery
collection DOAJ
language English
format Article
sources DOAJ
author Zihe Zhang
Shu Zhao
Boya Wang
Haijun Yu
spellingShingle Zihe Zhang
Shu Zhao
Boya Wang
Haijun Yu
Local Redox Reaction of High Valence Manganese in Li2MnO3-Based Lithium Battery Cathodes
Cell Reports Physical Science
Li-rich layered oxides
local redox reaction
first-principles computation
Li-ion battery
author_facet Zihe Zhang
Shu Zhao
Boya Wang
Haijun Yu
author_sort Zihe Zhang
title Local Redox Reaction of High Valence Manganese in Li2MnO3-Based Lithium Battery Cathodes
title_short Local Redox Reaction of High Valence Manganese in Li2MnO3-Based Lithium Battery Cathodes
title_full Local Redox Reaction of High Valence Manganese in Li2MnO3-Based Lithium Battery Cathodes
title_fullStr Local Redox Reaction of High Valence Manganese in Li2MnO3-Based Lithium Battery Cathodes
title_full_unstemmed Local Redox Reaction of High Valence Manganese in Li2MnO3-Based Lithium Battery Cathodes
title_sort local redox reaction of high valence manganese in li2mno3-based lithium battery cathodes
publisher Elsevier
series Cell Reports Physical Science
issn 2666-3864
publishDate 2020-05-01
description Summary: Li2MnO3 endows Li-rich layered oxides with a superior energy density; however, its electron transfer mechanism is still unclear. Here, the electronic and thermodynamic behavior of LixMnO3 (x = 0.5–2) is determined using first-principles computations. The cationic redox, anionic redox, and local electron exchange in Mn-O polyhedron are revealed. An obvious electron donation inclination of manganese is demonstrated when the Li+ content is low. Through ab initio molecular dynamics, high valence Mn6+ and Mn7+ are generated in the form of MnO4 tetrahedrons with structural transformation toward a disordered structure, controlled by the Li+ content and dynamic energy barrier. Furthermore, a local redox reaction between Mn6+ or Mn7+ and their surrounding oxygen atoms is elucidated. Consequently, a comprehensive understanding regarding the electron transfer in LixMnO3 is provided. Our results bring insight regarding the electron transfer mechanism in Li-rich layered oxide cathode materials and encourage further reconsideration and investigation into its redox mechanism.
topic Li-rich layered oxides
local redox reaction
first-principles computation
Li-ion battery
url http://www.sciencedirect.com/science/article/pii/S2666386420300552
work_keys_str_mv AT zihezhang localredoxreactionofhighvalencemanganeseinli2mno3basedlithiumbatterycathodes
AT shuzhao localredoxreactionofhighvalencemanganeseinli2mno3basedlithiumbatterycathodes
AT boyawang localredoxreactionofhighvalencemanganeseinli2mno3basedlithiumbatterycathodes
AT haijunyu localredoxreactionofhighvalencemanganeseinli2mno3basedlithiumbatterycathodes
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