Rate dependent structural changes, cycling stability, and Li-ion diffusivity in a layered-layered oxide cathode material after prolonged cycling
Li-Rich layered oxide (LLO) cathode materials,xLi2MnO3·(1 −x)LiCoO2(0 <x< 1, M = Mn, Ni, Co,etc.) are considered promising cathode materials in Li-ion batteries for large scale applications. This is because they provide high specific capacities of up to 250 mA h g−1. An electrode material with...
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th-mahidol.766032022-08-04T15:54:44Z Rate dependent structural changes, cycling stability, and Li-ion diffusivity in a layered-layered oxide cathode material after prolonged cycling Songyoot Kaewmala Wanwisa Limphirat Visittapong Yordsri Jeffrey Nash Sutham Srilomsak Aniwat Kesorn Pimpa Limthongkul Nonglak Meethong Thailand National Energy Technology Center (ENTEC) Udon Thani Rajabhat University Khon Kaen University Thailand National Metal and Materials Technology Center Mahidol University Synchrotron Light Research Institute Chemistry Energy Materials Science Li-Rich layered oxide (LLO) cathode materials,xLi2MnO3·(1 −x)LiCoO2(0 <x< 1, M = Mn, Ni, Co,etc.) are considered promising cathode materials in Li-ion batteries for large scale applications. This is because they provide high specific capacities of up to 250 mA h g−1. An electrode material with high energy density and high rate capability (fast charging) is required in EVs to enhance mileage and reduce charging time, respectively. The fast-charging capability of Li-ion batteries is largely determined by the electrochemical kinetic behaviors of their electrodes. Therefore, a deeper understanding about the relationship between cycling rate, structural stability, cyclability, and Li-ion diffusivity behaviors of electrode materials is a critical key to explore high-performance electrode materials for EVs and other high rate applications. In this work, the effects of cycling rates on the structural changes, cycling stability and Li-ion diffusion coefficients of a 0.5Li2MnO3·0.5LiCoO2material were investigated. The results show that the activation of the Li2MnO3component was controlled by the cycling rate. A high cycling rate effectively reduced the Li2MnO3activation and spinel phase evolution, bringing about better cycling stability, and faster Li-ion diffusion after prolonged cycling. 2022-08-04T08:23:18Z 2022-08-04T08:23:18Z 2021-06-28 Article Journal of Materials Chemistry A. Vol.9, No.24 (2021), 14004-14012 10.1039/d1ta02293h 20507496 20507488 2-s2.0-85108608807 https://repository.li.mahidol.ac.th/handle/123456789/76603 Mahidol University SCOPUS https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=85108608807&origin=inward |
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Chemistry Energy Materials Science Songyoot Kaewmala Wanwisa Limphirat Visittapong Yordsri Jeffrey Nash Sutham Srilomsak Aniwat Kesorn Pimpa Limthongkul Nonglak Meethong Rate dependent structural changes, cycling stability, and Li-ion diffusivity in a layered-layered oxide cathode material after prolonged cycling |
| description |
Li-Rich layered oxide (LLO) cathode materials,xLi2MnO3·(1 −x)LiCoO2(0 <x< 1, M = Mn, Ni, Co,etc.) are considered promising cathode materials in Li-ion batteries for large scale applications. This is because they provide high specific capacities of up to 250 mA h g−1. An electrode material with high energy density and high rate capability (fast charging) is required in EVs to enhance mileage and reduce charging time, respectively. The fast-charging capability of Li-ion batteries is largely determined by the electrochemical kinetic behaviors of their electrodes. Therefore, a deeper understanding about the relationship between cycling rate, structural stability, cyclability, and Li-ion diffusivity behaviors of electrode materials is a critical key to explore high-performance electrode materials for EVs and other high rate applications. In this work, the effects of cycling rates on the structural changes, cycling stability and Li-ion diffusion coefficients of a 0.5Li2MnO3·0.5LiCoO2material were investigated. The results show that the activation of the Li2MnO3component was controlled by the cycling rate. A high cycling rate effectively reduced the Li2MnO3activation and spinel phase evolution, bringing about better cycling stability, and faster Li-ion diffusion after prolonged cycling. |
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Thailand National Energy Technology Center (ENTEC) |
| author_facet |
Thailand National Energy Technology Center (ENTEC) Songyoot Kaewmala Wanwisa Limphirat Visittapong Yordsri Jeffrey Nash Sutham Srilomsak Aniwat Kesorn Pimpa Limthongkul Nonglak Meethong |
| format |
Article |
| author |
Songyoot Kaewmala Wanwisa Limphirat Visittapong Yordsri Jeffrey Nash Sutham Srilomsak Aniwat Kesorn Pimpa Limthongkul Nonglak Meethong |
| author_sort |
Songyoot Kaewmala |
| title |
Rate dependent structural changes, cycling stability, and Li-ion diffusivity in a layered-layered oxide cathode material after prolonged cycling |
| title_short |
Rate dependent structural changes, cycling stability, and Li-ion diffusivity in a layered-layered oxide cathode material after prolonged cycling |
| title_full |
Rate dependent structural changes, cycling stability, and Li-ion diffusivity in a layered-layered oxide cathode material after prolonged cycling |
| title_fullStr |
Rate dependent structural changes, cycling stability, and Li-ion diffusivity in a layered-layered oxide cathode material after prolonged cycling |
| title_full_unstemmed |
Rate dependent structural changes, cycling stability, and Li-ion diffusivity in a layered-layered oxide cathode material after prolonged cycling |
| title_sort |
rate dependent structural changes, cycling stability, and li-ion diffusivity in a layered-layered oxide cathode material after prolonged cycling |
| publishDate |
2022 |
| url |
https://repository.li.mahidol.ac.th/handle/123456789/76603 |
| _version_ |
1763495978533388288 |