应用循环伏安、恒电流充放电和电化学阻抗技术研究了尖晶石L iMn2O4于室温离子液体电解液中的电化学性质.实验表明,以室温离子液体作电解液,L iMn2O4的首次放电容量可达108.2 mAh/g、循环效率高于90%,温度和电流密度显著影响电极的电化学性能.交流阻抗测定了L i+在电极/电解液相界面迁移的活化能,为55 kJ/mol.根据界面反应的高活化能解释了L iMn2O4在该离子液体电解液中低温性能和倍率充放电性能不佳的原因.
The electrochemical behavior of spinel LiMn_(2)O_(4)electrode in ionic liquid electrolyte was investigated by using cyclic voltammetry, galvanostatic charge-discharge and ACimpedance techniques. The results reveal that the spinel LiMn_(2)O_(4)can be effectively cycled in electrolyte based on the ionic liquid with discharge capacity of 108.2mAh/g and Coulombic efficiency of more than 90% in the first cycle at room temperature. Temperature and current density play an important role in the electrode performances. The activation energy for lithium ion transfer through interface between the electrode and the electrolyte was evaluated by AC impedance spectroscopy. The high activation energy accounts for the poor cell performance at low temperature and for its poor rate capability.
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