▎ 摘　　要

Graphene-based materials are cathodes of Al-ion batteries and have attracted the attention of researchers worldwide. However, reasons for self-discharge in Al/graphene batteries have not been studied in depth. In the present work, a pseudo-capacitive reaction is proposed to be a probable cause of the self-discharge. Quantitative analysis of the capacitance process and diffusion-control process is critical for the pseudo-capacitive behavior in Al/graphene batteries. Two self-supported graphene cathodes (RH-GOP and RN-GOP) were successfully produced from graphene oxides (GO) reduced with hydriodic acid and hydrazine vapor, respectively. RH-GOP and RN-GOP cathodes enabled the delivery of considerably high specific capacities of 81.5 mAh g(-1) and 92.8 mAh g(-1), at the current density of 2 A g-1. In addition, the activation processes of both materials were observed during 200 cycles of the charge-discharge process. From a quantitative perspective, the ratios of faradaic pseudo-capacitance to the total capacity of the RH-GOP and RN-GOP cathode were 48.6% and 38.5%, respectively, at a scanning rate of 5.0 mV s(-1). It is found that the proportion of faradaic pseudo-capacitance will increase as cyclic voltammetry scanning increases, which indicates the existence of pseudo-capacitance being the reason why it an Al/graphene battery has to be charged-discharged at high current densities to maintain normal operation.