GUO Hua-jun, LI Xin-hai, ZHANG Xin-ming, WANG Hong-qiang, WANG Zhi-xing, PENG Wen-jie. 锂在人造石墨、中间相炭微球及无定形碳中的扩散系数(英文). New Carbon Mater., 2007, 22(01): 7-11.
Citation:
GUO Hua-jun, LI Xin-hai, ZHANG Xin-ming, WANG Hong-qiang, WANG Zhi-xing, PENG Wen-jie. 锂在人造石墨、中间相炭微球及无定形碳中的扩散系数(英文). New Carbon Mater., 2007, 22(01): 7-11.
GUO Hua-jun, LI Xin-hai, ZHANG Xin-ming, WANG Hong-qiang, WANG Zhi-xing, PENG Wen-jie. 锂在人造石墨、中间相炭微球及无定形碳中的扩散系数(英文). New Carbon Mater., 2007, 22(01): 7-11.
Citation:
GUO Hua-jun, LI Xin-hai, ZHANG Xin-ming, WANG Hong-qiang, WANG Zhi-xing, PENG Wen-jie. 锂在人造石墨、中间相炭微球及无定形碳中的扩散系数(英文). New Carbon Mater., 2007, 22(01): 7-11.
College of Metallurgical Science and Engineering,Central South University,Changsha 410083,China; 2.College of Materials Science and Engineering,Central South University,Changsha 410083,China
The structures of pyrolytic sugar carbon, resin carbon, artificial graphite, and mesocarbon microbeads (MCMBs) and the diffusion coefficient of lithium in them were determined by X-ray diffraction and potential step chronoamperometry measurements. It was found that the diffusion coefficient of lithium was strongly dependent on the degree of discharge and the structure of the carbon anodes. As the discharge degree increased, the diffusion coefficient of lithium in MCMB anodes decreased from 4.43×10-9 cm2/s to 5.24×10-10 cm2/s. At half discharge, the diffusion coefficients of lithium in sugar carbon, resin carbon, artificial graphite, and MCMB anode were 1.4×10-10 cm2/s, 5.75×10-10 cm2/s, 1.24×10-9 cm2/s, 2.1×10-9 cm2/s, respectively, showing that diffusion of lithium in soft carbons (artificial graphite and MCMBs) was much easier than in hard carbons such as sugar and resin carbon.