摘要
MoO_(3) is one of the most promising anode materials for aqueous aluminum batteries due to its high theoretical capacity and suitable aluminum insertion/de-insertion potential.However,the inferior cycling stability limits its further application,and the failure mechanism is still unclear.In this article,we provide a straightforward potential regulation technique to manage phase evolution during the charge/discharge process,which ultimately results in a markedly enhanced MoO_(3) electrode cycling stability.The failure mechanism study reveals that the excessive oxidation of the electrode during charge/discharge generates the H_(0.34)MoO_(3) phase,which has high solubility and is the primary cause of MoO_(3) deactivation.Although the dissolved Mo species will be deposited onto the electrode sheet again,the deposition is not electrochemically active and cannot contribute to the capacitance.Controlling the cutoff potential prevented the production of H_(0.34)MoO_(3),resulting in excellent cycling performance(80.1% capacity retention after 4000 cycles).The as-assembled α-MoO_(3)//MnO_(2) full battery exhibits high discharge plateaus(1.4 and 0.9 V),large specific capacity(200 mAhg^(-1) at 2 Ag^(-1)),and ultra-high coulombic efficiency(99%).The research presented here may contribute to the development of highly stable electrode materials for aqueous batteries.
基金
the Youth Program of National Natural Science Foundation of China(grant nos.21905300,52277229,22109180,and 51877216)
Taishan Scholar Foundation(grant no.tspd20210308)
National Key Research and Development of China(grant no.2022YFA1503400)
Key Projects of Shandong Key R&D plan(grant no.2019JZZY010506)
Fundamental Research Funds for the Central Universities(grant no.21CX06011A)
111 Program of National College Disciplinary Innovation(grant no.B03031)
Natural Science Foundation of Shandong Province(grant nos.ZR202103040491 and ZR2020MB078)
Research Project of State Key Laboratory for Heavy Oil Processing(grant no.SLKZZKT-2021).
