Lowering charge transfer barrier of LiMn2O4 via nickel surface doping to enhance Li+ intercalation kinetics at subzero temperatures
Sluggish interfacial kinetics leading to considerable loss of energy and power capabilities at subzero temperatures is still a big challenge to overcome for Li-ion batteries operating under extreme environmental conditions. Herein, using LiMn2O4 as the model system, we demonstrated that nickel surfa...
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sg-ntu-dr.10356-1390052023-07-14T16:04:11Z Lowering charge transfer barrier of LiMn2O4 via nickel surface doping to enhance Li+ intercalation kinetics at subzero temperatures Zhang, Wei Sun, Xiaoli Tang, Yuxin Xia, Huarong Zeng, Yi Qiao, Liang Zhu, Zhiqiang Lv, Zhisheng Zhang, Yanyan Ge, Xiang Xi, Shibo Wang, Zhiguo Du, Yonghua Chen, Xiaodong School of Materials Science & Engineering Innovative Centre for Flexible Devices Engineering::Materials::Energy materials Lithium Ion Battery Low Temperature Sluggish interfacial kinetics leading to considerable loss of energy and power capabilities at subzero temperatures is still a big challenge to overcome for Li-ion batteries operating under extreme environmental conditions. Herein, using LiMn2O4 as the model system, we demonstrated that nickel surface doping to construct a new interface owning lower charge transfer energy barrier, could effectively facilitate the interfacial process and inhibit the capacity loss with decreased temperature. Detailed investigations on the charge transfer process via electrochemical impedance spectroscopy and density functional theory calculation, indicate that the interfacial chemistry tuning could effectively lower the activation energy of charge transfer process by nearly 20%, endowing the cells with ∼75.4% capacity at −30 °C, far surpassing the hardly discharged unmodified counterpart. This control of surface chemistry to tune interfacial dynamics proposes insights and design ideas for batteries to well survive under thermal extremes. NRF (Natl Research Foundation, S’pore) Accepted version 2020-05-14T09:55:34Z 2020-05-14T09:55:34Z 2019 Journal Article Zhang, W., Sun, X., Tang, Y., Xia, H., Zeng, Y., Qiao, L., . . . Chen, X. (2019). Lowering charge transfer barrier of LiMn2O4 via nickel surface doping to enhance Li+ intercalation kinetics at subzero temperatures. Journal of the American Chemical Society, 141(36), 14038-14042. doi:10.1021/jacs.9b05531 0002-7863 https://hdl.handle.net/10356/139005 10.1021/jacs.9b05531 31448603 2-s2.0-85072057500 36 141 14038 14042 en Journal of the American Chemical Society This document is the Accepted Manuscript version of a Published Work that appeared in final form in Journal of the American Chemical Society, copyright © American Chemical Society after peer review and technical editing by the publisher. To access the final edited and published work see https://doi.org/10.1021/jacs.9b05531 application/pdf |
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Engineering::Materials::Energy materials Lithium Ion Battery Low Temperature Zhang, Wei Sun, Xiaoli Tang, Yuxin Xia, Huarong Zeng, Yi Qiao, Liang Zhu, Zhiqiang Lv, Zhisheng Zhang, Yanyan Ge, Xiang Xi, Shibo Wang, Zhiguo Du, Yonghua Chen, Xiaodong Lowering charge transfer barrier of LiMn2O4 via nickel surface doping to enhance Li+ intercalation kinetics at subzero temperatures |
| description |
Sluggish interfacial kinetics leading to considerable loss of energy and power capabilities at subzero temperatures is still a big challenge to overcome for Li-ion batteries operating under extreme environmental conditions. Herein, using LiMn2O4 as the model system, we demonstrated that nickel surface doping to construct a new interface owning lower charge transfer energy barrier, could effectively facilitate the interfacial process and inhibit the capacity loss with decreased temperature. Detailed investigations on the charge transfer process via electrochemical impedance spectroscopy and density functional theory calculation, indicate that the interfacial chemistry tuning could effectively lower the activation energy of charge transfer process by nearly 20%, endowing the cells with ∼75.4% capacity at −30 °C, far surpassing the hardly discharged unmodified counterpart. This control of surface chemistry to tune interfacial dynamics proposes insights and design ideas for batteries to well survive under thermal extremes. |
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School of Materials Science & Engineering |
| author_facet |
School of Materials Science & Engineering Zhang, Wei Sun, Xiaoli Tang, Yuxin Xia, Huarong Zeng, Yi Qiao, Liang Zhu, Zhiqiang Lv, Zhisheng Zhang, Yanyan Ge, Xiang Xi, Shibo Wang, Zhiguo Du, Yonghua Chen, Xiaodong |
| format |
Article |
| author |
Zhang, Wei Sun, Xiaoli Tang, Yuxin Xia, Huarong Zeng, Yi Qiao, Liang Zhu, Zhiqiang Lv, Zhisheng Zhang, Yanyan Ge, Xiang Xi, Shibo Wang, Zhiguo Du, Yonghua Chen, Xiaodong |
| author_sort |
Zhang, Wei |
| title |
Lowering charge transfer barrier of LiMn2O4 via nickel surface doping to enhance Li+ intercalation kinetics at subzero temperatures |
| title_short |
Lowering charge transfer barrier of LiMn2O4 via nickel surface doping to enhance Li+ intercalation kinetics at subzero temperatures |
| title_full |
Lowering charge transfer barrier of LiMn2O4 via nickel surface doping to enhance Li+ intercalation kinetics at subzero temperatures |
| title_fullStr |
Lowering charge transfer barrier of LiMn2O4 via nickel surface doping to enhance Li+ intercalation kinetics at subzero temperatures |
| title_full_unstemmed |
Lowering charge transfer barrier of LiMn2O4 via nickel surface doping to enhance Li+ intercalation kinetics at subzero temperatures |
| title_sort |
lowering charge transfer barrier of limn2o4 via nickel surface doping to enhance li+ intercalation kinetics at subzero temperatures |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/139005 |
| _version_ |
1773551376193814528 |