Electrochimica Acta, Vol.48, No.4, 419-430, 2002
Mechanism of lithium transport through an MCMB heat-treated at 800-1200 degrees C
Mechanism of lithium transport through a mesocarbon-microbeads (MCMB) heat-treated at 800-1200 degreesC was elucidated in I M LiPF6-ethylene carbonate-diethyl carbonate (50:50 vol.%) solution by the quantitative analysis of potentiostatic current transient considering the difference in the relative amount of lithium deintercalation sites having different activation energies for lithium deintercalation. From the coincidence between the current transients experimentally measured and theoretically calculated based upon the modified McNabb-Foster equation along with 'cell-impedance-controlled' constraint as the governing equation with the boundary condition, respectively, it is suggested that lithium transport through the MCMB electrode is limited by the 'cell-impedance', and at the same time the difference in the kinetics of lithium transport between through the four different lithium deintercalation sites is due to the difference in activation energy for lithium deintercalation between from the four different lithium deintercalation sites present within the MCMB. Moreover, it is realised that since the degree of microcrystallinity of the MCMB is increased with rising heat-treatment temperature, the relative charge amount of lithium deintercalated from the lattice-site is increased, but that amount from the extra-sites is decreased. Thus, the inflexion point, i.e. 'quasi-current plateau' in the current transient is less clearly observed with rising heat-treatment temperature.
Keywords:mesocarbon-microbeads (MCMB);potentiostatic current transient;McNabb-Foster equation;cell-impedence;numerical simulation