New Chemical Materials >

2021 , Vol. 49 >Issue 1: 23 - 27

DOI: https://doi.org/10.19817/j.cnki.issn 1006-3536.2021.01.006

Property of rGO and application in Mg-based hydrogen storage material

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  • 1. College of Chemical and Engineering,Guizhou University of Science and Technology,Bijie 551700;
    2. College of Chemical and Environmental Engineering,China University of Mining and Technology-Beijing,Beijing 100083;
    3. Shandong Provincial Research Institute of Coal Geology Planning and Exploration,Jinan 250104

Received date: 2020-06-29

  Revised date: 2020-10-22

  Online published: 2021-01-27

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Abstract

Graphene(rGO) is widely concerned in the field of hydrogen storage because of its excellent physical and chemical properties.The research progress of rGO as hydrogen storage material in recent years was reviewed,and introduced the different methods to improve the hydrogen storage performance of rGO,such as doping,vacancy defect and so on.The application of rGO in Mg-based hydrogen storage material was reviewed,and studied the influence of different catalysts (such as reactive metals,intermetallic compounds,metal halides,transition metal oxides) supported by rGO on the performance of Mg-based hydrogen storage material.The catalytic mechanism of rGO to Mg-based hydrogen storage material were analyzed.It was found that the interaction mode between rGO and hydrogen molecules was physical adsorption and chemical adsorption,and rGO played the role of catalysis,cocatalysis and inhibition of grain aggregation and growth in Mg-based hydrogen storage material.When rGO was applied to solid metal hydride,the synergistic effect between the two can make the hydrogen storage system shown high activity and selectivity,which can provide a new idea for the construction of high-performance materials in the field of hydrogen storage.

Key words: graphene; hydrogen; catalyst; catalyst support; Mg-based hydrogen storage material

Cite this article

Yang Minjian, Zhu Xueqin, Zhou Lili, Deng Qi, Wei Chan . Property of rGO and application in Mg-based hydrogen storage material[J]. New Chemical Materials, 2021 , 49(1) : 23 -27 . DOI: 10.19817/j.cnki.issn 1006-3536.2021.01.006

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