Influence of sintering temperature on the morphology and cycle performance of nanoscale porous materials LiFe_(0.75)Mn_(0.25)PO_4/C

Yuanchao Du; Feng Liang; Jinhua Lu; Huangkai Zhou; Jian Wu; Tao Qu; Yongnian Dai; Yaochun Yao; Bin Yang

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Influence of sintering temperature on the morphology and cycle performance of nanoscale porous materials LiFe_(0.75)Mn_(0.25)PO_4/C

机译：烧结温度对纳米多孔材料LiFe_（0.75）Mn_（0.25）PO_4 / C的形貌和循环性能的影响

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摘要

Nano porous materials LiFe0.75Mn0.25PO4/C were prepared by sol-gel method. The influences of sintering temperature on particle size, pore size distribution and cycling performance were studied. The results show that ratio of the mesopore in diameter 9.5 nm increases gradually with the increase of sintering temperature. The material sintered at 750 °C has high crystallinity, the particle size under 100 nm, the specific surface area of 80.3m2 g−1, about 3 nm carbon coating, and higher ratio of the mesopore in diameter 9.5 nm. These are beneficial to the diffusion of lithium ion and the transfer of electrons, and high electrochemical performance material has been obtained. The initial discharge specific capacity is 120.28 mAhg−1, it remains 80.71mAhg−1at 10C after 600 cycles.

机译：采用溶胶-凝胶法制备了纳米多孔材料LiFe0.75Mn0.25PO4 / C。研究了烧结温度对粒度，孔径分布和循环性能的影响。结果表明，随着烧结温度的升高，中孔直径9.5 nm的比例逐渐增大。在750 C烧结的材料具有较高的结晶度，100 nm以下的粒径，80.3m2 g-1的比表面积，约3 nm的碳涂层以及直径9.5 nm的中孔比例更高。这些有利于锂离子的扩散和电子的转移，并且已经获得了高电化学性能的材料。初始放电比容量为120.28 mAhg-1，经过600次循环后在10C时仍为80.71mAhg-1。

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来源
《Journal of Energy Storage》 |2018年第10期|226-231|共6页
作者
Yuanchao Du; Feng Liang; Jinhua Lu; Huangkai Zhou; Jian Wu; Tao Qu; Yongnian Dai; Yaochun Yao; Bin Yang;
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Faculty of Metallurgical and Energy Engineering, National Engineering Laboratory for Vacuum Metallurgy, China National and Local Joint Engineering Laboratory for Lithium-ion Batteries and Materials Preparation Technology, Kunming University of Science and Technology;

Faculty of Metallurgical and Energy Engineering, National Engineering Laboratory for Vacuum Metallurgy, China National and Local Joint Engineering Laboratory for Lithium-ion Batteries and Materials Preparation Technology, Kunming University of Science and Technology;

Faculty of Metallurgical and Energy Engineering, National Engineering Laboratory for Vacuum Metallurgy, China National and Local Joint Engineering Laboratory for Lithium-ion Batteries and Materials Preparation Technology, Kunming University of Science and Technology;

Faculty of Metallurgical and Energy Engineering, National Engineering Laboratory for Vacuum Metallurgy, China National and Local Joint Engineering Laboratory for Lithium-ion Batteries and Materials Preparation Technology, Kunming University of Science and Technology;

Faculty of Metallurgical and Energy Engineering, National Engineering Laboratory for Vacuum Metallurgy, China National and Local Joint Engineering Laboratory for Lithium-ion Batteries and Materials Preparation Technology, Kunming University of Science and Technology;

Faculty of Metallurgical and Energy Engineering, National Engineering Laboratory for Vacuum Metallurgy, China National and Local Joint Engineering Laboratory for Lithium-ion Batteries and Materials Preparation Technology, Kunming University of Science and Technology;

Faculty of Metallurgical and Energy Engineering, National Engineering Laboratory for Vacuum Metallurgy, China National and Local Joint Engineering Laboratory for Lithium-ion Batteries and Materials Preparation Technology, Kunming University of Science and Technology;

Faculty of Metallurgical and Energy Engineering, National Engineering Laboratory for Vacuum Metallurgy, China National and Local Joint Engineering Laboratory for Lithium-ion Batteries and Materials Preparation Technology, Kunming University of Science and Technology;

Faculty of Metallurgical and Energy Engineering, National Engineering Laboratory for Vacuum Metallurgy, China National and Local Joint Engineering Laboratory for Lithium-ion Batteries and Materials Preparation Technology, Kunming University of Science and Technology;

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Sintering temperature; Nanoscale porous materials; Particle size; Pore size; Distribution; Cycle performance;

机译：烧结温度纳米级多孔材料粒径孔径分布循环性能;

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Influence of sintering temperature on the morphology and cycle performance of nanoscale porous materials LiFe_(0.75)Mn_(0.25)PO_4/C

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