| Literature DB >> 26305572 |
Jiaxin Zheng1, Yuyang Hou2,3, Yandong Duan1, Xiaohe Song1, Yi Wei1, Tongchao Liu1, Jiangtao Hu1, Hua Guo1, Zengqing Zhuo1, Lili Liu3, Zheng Chang3, Xiaowei Wang3, Danylo Zherebetskyy4, Yanyan Fang5, Yuan Lin5, Kang Xu6, Lin-Wang Wang4, Yuping Wu2,3, Feng Pan1.
Abstract
LiFePO4 has long been held as one of the most promising battery cathode for its high energy storage capacity. Meanwhile, although extensive studies have been conducted on the interfacial chemistries in Li-ion batteries,1-3 little is known on the atomic level about the solid-liquid interface of LiFePO4/electrolyte. Here, we report battery cathode consisted with nanosized LiFePO4 particles in aqueous electrolyte with an high charging and discharging rate of 600 C (3600/600 = 6 s charge time, 1 C = 170 mAh g(-1)) reaching 72 mAh g(-1) energy storage (42% of the theoretical capacity). By contrast, the accessible capacity sharply decreases to 20 mAh g(-1) at 200 C in organic electrolyte. After a comprehensive electrochemistry tests and ab initio calculations of the LiFePO4-H2O and LiFePO4-EC (ethylene carbonate) systems, we identified the transient formation of a Janus hydrated interface in the LiFePO4-H2O system, where the truncated symmetry of solid LiFePO4 surface is compensated by the chemisorbed H2O molecules, forming a half-solid (LiFePO4) and half-liquid (H2O) amphiphilic coordination environment that eases the Li desolvation process near the surface, which makes a fast Li-ion transport across the solid/liquid interfaces possible.Entities:
Keywords: LiFePO4; ab initio calculations; aqueous electrolyte; organic electrolyte; rate performance; solid−liquid interface
Year: 2015 PMID: 26305572 DOI: 10.1021/acs.nanolett.5b02379
Source DB: PubMed Journal: Nano Lett ISSN: 1530-6984 Impact factor: 11.189