posted on 2017-08-03, 00:00authored byYandong Duan, Bingkai Zhang, Jiaxin Zheng, Jiangtao Hu, Jianguo Wen, Dean J. Miller, Pengfei Yan, Tongchao Liu, Hua Guo, Wen Li, Xiaohe Song, Zengqing Zhuo, Chaokun Liu, Hanting Tang, Rui Tan, Zonghai Chen, Yang Ren, Yuan Lin, Wanli Yang, Chong-Min Wang, Lin-Wang Wang, Jun Lu, Khalil Amine, Feng Pan
Because
of their enhanced kinetic properties, nanocrystallites
have received much attention as potential electrode materials for
energy storage. However, because of the large specific surface areas
of nanocrystallites, they usually suffer from decreased energy density,
cycling stability, and effective electrode capacity. In this work,
we report a size-dependent excess capacity beyond theoretical value
(170 mA h g–1) by introducing extra lithium storage
at the reconstructed surface in nanosized LiFePO4 (LFP)
cathode materials (186 and 207 mA h g–1 in samples
with mean particle sizes of 83 and 42 nm, respectively). Moreover,
this LFP composite also shows excellent cycling stability and high
rate performance. Our multimodal experimental characterizations and
ab initio calculations reveal that the surface extra lithium storage
is mainly attributed to the charge passivation of Fe by the surface
C–O–Fe bonds, which can enhance binding energy for surface
lithium by compensating surface Fe truncated symmetry to create two
types of extra positions for Li-ion storage at the reconstructed surfaces.
Such surface reconstruction nanotechnology for excess Li-ion storage
makes full use of the large specific surface area of the nanocrystallites,
which can maintain the fast Li-ion transport and greatly enhance the
capacity. This discovery and nanotechnology can be used for the design
of high-capacity and efficient lithium ion batteries.