Impact of surface Li-containing rock-salt phase on electrochemical performance of Li- and Mn-rich cathodes

The synthesis of Li- and Mn-rich layered oxides is often hindered by the formation of a disordered rock-salt-type phase, which is believed to have a negative impact on their electrochemical performance due to the inherently low electrochemical activity of this phase. Herein, we employ a two-step app...

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Published inJournal of power sources Vol. 649; p. 237445
Main Authors Zhao, Tian, Cai, Guanqun, Zhai, Xinyue, Wang, Suning, Yang, Xiaoxia, Peng, Kang-Shun, Chen, Meng-Cheng, Hung, Sung-Fu, Kong, Xiangyang, Li, Mingtao, Tang, Wei, Zhou, Leidang, Hua, Weibo
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.09.2025
Subjects
Formation kinetics
Li- and Mn-rich oxides
Li-containing rock-salt-type phase
Lithium-ion batteries
Structural stability
Lithium-ion batteries
Li-containing rock-salt-type phase
Structural stability
Li- and Mn-rich oxides
Formation kinetics
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Abstract The synthesis of Li- and Mn-rich layered oxides is often hindered by the formation of a disordered rock-salt-type phase, which is believed to have a negative impact on their electrochemical performance due to the inherently low electrochemical activity of this phase. Herein, we employ a two-step approach involving spray pyrolysis followed by calcination to prepare Co-free Li[Li0.2Ni0.2Mn0.6]O2 (LLNMO) oxides. The disordered Li-containing rock-salt-type phase emerges on the surface of LLNMO crystallites at elevated heating temperatures (≥930 °C). The formation kinetics of the Li-containing rock-salt-type phase is determined to follow a reaction-diffusion process. For LLNMO-950 (950 °C) with a coherent structure comprising both layered and thicker Li-containing rock-salt-type phases, the discharge capacity exhibits a progressive increase within the initial 52 cycles. The lattice parameters of the rock-salt structure undergo variations during electrochemical cycling, indicating that the rock-salt-type phase is not completely electrochemically inactive. By adjusting the heating temperature (930 °C, denoted as LLNMO-930), we introduce a thin disordered Li-containing rock-salt-type phase (approximately 2 nm thick) on the primary particle surface of LLNMO. The LLNMO-930 exhibits good electrochemical performance, with a high energy density retention of 95 % and a voltage decay of 0.3 V after 100 cycles at 0.1 C. [Display omitted] •The formation kinetics of the surface rock-salt-type phase were investigated.•Surface rock-salt-type phase thickness affects the electrochemical performance.•The surface rock-salt-type phase is not completely electrochemically inactive.•LLNMO-930 with a thin rock-salt-type phase shows good electrochemical performance.
AbstractList The synthesis of Li- and Mn-rich layered oxides is often hindered by the formation of a disordered rock-salt-type phase, which is believed to have a negative impact on their electrochemical performance due to the inherently low electrochemical activity of this phase. Herein, we employ a two-step approach involving spray pyrolysis followed by calcination to prepare Co-free Li[Li0.2Ni0.2Mn0.6]O2 (LLNMO) oxides. The disordered Li-containing rock-salt-type phase emerges on the surface of LLNMO crystallites at elevated heating temperatures (≥930 °C). The formation kinetics of the Li-containing rock-salt-type phase is determined to follow a reaction-diffusion process. For LLNMO-950 (950 °C) with a coherent structure comprising both layered and thicker Li-containing rock-salt-type phases, the discharge capacity exhibits a progressive increase within the initial 52 cycles. The lattice parameters of the rock-salt structure undergo variations during electrochemical cycling, indicating that the rock-salt-type phase is not completely electrochemically inactive. By adjusting the heating temperature (930 °C, denoted as LLNMO-930), we introduce a thin disordered Li-containing rock-salt-type phase (approximately 2 nm thick) on the primary particle surface of LLNMO. The LLNMO-930 exhibits good electrochemical performance, with a high energy density retention of 95 % and a voltage decay of 0.3 V after 100 cycles at 0.1 C. [Display omitted] •The formation kinetics of the surface rock-salt-type phase were investigated.•Surface rock-salt-type phase thickness affects the electrochemical performance.•The surface rock-salt-type phase is not completely electrochemically inactive.•LLNMO-930 with a thin rock-salt-type phase shows good electrochemical performance.
ArticleNumber 237445
Author Li, Mingtao
Hua, Weibo
Hung, Sung-Fu
Cai, Guanqun
Yang, Xiaoxia
Peng, Kang-Shun
Wang, Suning
Tang, Wei
Zhai, Xinyue
Kong, Xiangyang
Zhao, Tian
Zhou, Leidang
Chen, Meng-Cheng
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  givenname: Kang-Shun
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  fullname: Peng, Kang-Shun
  organization: Department of Applied Chemistry, National Yang Ming Chiao Tung University, 1001 University Road, 30010, Hsinchu, Taiwan
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  givenname: Meng-Cheng
  surname: Chen
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  organization: Department of Applied Chemistry, National Yang Ming Chiao Tung University, 1001 University Road, 30010, Hsinchu, Taiwan
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  givenname: Sung-Fu
  orcidid: 0000-0002-7423-2723
  surname: Hung
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  givenname: Wei
  orcidid: 0000-0002-0941-1071
  surname: Tang
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  email: zhould@xjtu.edu.cn
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  givenname: Weibo
  orcidid: 0000-0001-5372-4422
  surname: Hua
  fullname: Hua, Weibo
  email: weibo.hua@xjtu.edu.cn
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Keywords Lithium-ion batteries
Li-containing rock-salt-type phase
Structural stability
Li- and Mn-rich oxides
Formation kinetics
Language English
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Snippet The synthesis of Li- and Mn-rich layered oxides is often hindered by the formation of a disordered rock-salt-type phase, which is believed to have a negative...
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elsevier
SourceType Index Database
Publisher
StartPage 237445
SubjectTerms Formation kinetics
Li- and Mn-rich oxides
Li-containing rock-salt-type phase
Lithium-ion batteries
Structural stability
Title Impact of surface Li-containing rock-salt phase on electrochemical performance of Li- and Mn-rich cathodes
URI https://dx.doi.org/10.1016/j.jpowsour.2025.237445
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