MOF derived TiO2 with reversible magnesium pseudocapacitance for ultralong-life Mg metal batteries

[Display omitted] •An ultralong-life cathode in Mg metal battery was obtained.•Surface redox and pseudocapacitive mechanism for Mg storage are demonstrated.•The high ion migration on TiO2-UN@C interface is revealed. Magnesium metal batteries have attracted much attention due to the good safety, low...

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Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2021-08, Vol.418, p.128491, Article 128491
Main Authors: Cai, Xinyin, Xu, Yanan, An, Qinyou, Jiang, Yalong, Liu, Ziang, Xiong, Fangyu, Zou, Wenyuan, Zhang, Gang, Dai, Yuhang, Yu, Ruohan, Mai, Liqiang
Format: Article
Language:English
Subjects:
Mg metal batteries
Pseudocapacitance
Titanium dioxide
Ultralong-life
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Summary:[Display omitted] •An ultralong-life cathode in Mg metal battery was obtained.•Surface redox and pseudocapacitive mechanism for Mg storage are demonstrated.•The high ion migration on TiO2-UN@C interface is revealed. Magnesium metal batteries have attracted much attention due to the good safety, low cost of magnesium and high theoretical volumetric capacity. However, developing magnesium metal batteries is restricted by large polarization and sluggish kinetics during Mg insertion/deinsertion process. Herein, TiO2 ultrafine nanocrystals derived from Ti-metal–organic-framework (Ti-MOF) are applied as the cathodes in magnesium metal batteries. Remarkably, an ultralong life of the Mg(s) || TiO2 battery can be obtained during cycling (capacity retention of 75% after 1000 cycles). On the basis of in-situ XRD characterization and cyclic voltammetry analysis, a high pseudocapacitive performance is found, which results in the high kinetics. Moreover, according to Arrhenius behavior, carbon skeleton in TiO2 cathode can facilitate ion migration and Faraday reaction, thus improving the magnesium storage performance.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2021.128491