Electrochemical intercalation of Mg2+ in 3D hierarchically porous magnesium cobalt silicate and its application as an advanced cathode material in rechargeable magnesium batteries

We firstly report the formation of 3D hierarchically porous MgCoSiO4 and the electrochemical intercalation of the bivalent cation Mg2+ in MgCoSiO4 with regard to its use as a cathode material in rechargeable magnesium batteries. Reversible Mg2+ intercalation can be demonstrated and the process is en...

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Veröffentlicht in:	Journal of materials chemistry 2011, Vol.21 (33), p.12437-12443
Hauptverfasser:	NuLi, Yanna, Zheng, Yupei, Wang, Ying, Yang, Jun, Wang, Jiulin
Format:	Artikel
Sprache:	eng
Schlagworte:	Batteries Cathodes Electric batteries Grains Intercalation Magnesium Three dimensional Walls
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creator	NuLi, Yanna Zheng, Yupei Wang, Ying Yang, Jun Wang, Jiulin
description	We firstly report the formation of 3D hierarchically porous MgCoSiO4 and the electrochemical intercalation of the bivalent cation Mg2+ in MgCoSiO4 with regard to its use as a cathode material in rechargeable magnesium batteries. Reversible Mg2+ intercalation can be demonstrated and the process is enhanced by the use of a novel 3D hierarchically porous architecture, consisting of a network of macropores with several nanometre wall and mesopores at the boundaries of grains or between grains. It is suggested that the interconnected wall structure, dual porosity and high surface area reduces the solid-state diffusion lengths for Mg diffusion, facilitates electrolyte penetration into particles and provides a large number of active sites for charge-transfer reactions.
doi_str_mv	10.1039/c1jm10485c
format	Article
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subjects	Batteries Cathodes Electric batteries Grains Intercalation Magnesium Three dimensional Walls
title	Electrochemical intercalation of Mg2+ in 3D hierarchically porous magnesium cobalt silicate and its application as an advanced cathode material in rechargeable magnesium batteries
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