Open AccessElectroplating lithium transition metal oxides
Author(s) -
Huigang Zhang,
Hailong Ning,
John Busbee,
Zihan Shen,
Chadd Kiggins,
Yuyan Hua,
Janna Eaves,
Jerome Davis,
Tan Shi,
YuTsun Shao,
JianMin Zuo,
Xuhao Hong,
Yanbin Chan,
Shuangbao Wang,
Peng Wang,
Pengcheng Sun,
Sheng Xu,
Jinyun Liu,
Paul V. Braun
Publication year - 2017
Publication title -
science advances
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 5.928
H-Index - 146
ISSN - 2375-2548
DOI - 10.1126/sciadv.1602427
Subject(s) - electroplating , battery (electricity) , materials science , cathode , electrochemistry , lithium (medication) , molten salt , transition metal , flexibility (engineering) , energy storage , electrode , nanotechnology , chemical engineering , metallurgy , power (physics) , electrical engineering , chemistry , catalysis , medicine , physics , biochemistry , statistics , engineering , layer (electronics) , quantum mechanics , endocrinology , mathematics
Materials synthesis often provides opportunities for innovation. We demonstrate a general low-temperature (260°C) molten salt electrodeposition approach to directly electroplate the important lithium-ion (Li-ion) battery cathode materials LiCoO2, LiMn2O4, and Al-doped LiCoO2. The crystallinities and electrochemical capacities of the electroplated oxides are comparable to those of the powders synthesized at much higher temperatures (700° to 1000°C). This new growth method significantly broadens the scope of battery form factors and functionalities, enabling a variety of highly desirable battery properties, including high energy, high power, and unprecedented electrode flexibility.
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