• Title/Summary/Keyword: $MgH_x$-graphene composite

Search Result 2, Processing Time 0.02 seconds

Evaluation of Hydrogenation Behavior of MgHx-Graphene Composites by Mechanical Alloying (기계적 합금화법으로 제조한 MgHx-Graphene 복합재료의 수소화 거동 특성)

  • Lee, Soo-Sun;Lee, Na-Ri;Kim, Kyeong-Il;Hong, Tae-Whan
    • Journal of Hydrogen and New Energy
    • /
    • v.22 no.6
    • /
    • pp.780-786
    • /
    • 2011
  • Mg hydride had high hydrogen capacity (7.6%), lightweight and low cost materials and it was promising hydrogen storage material at high temperature. However, commercial applications of the Mg hydride are currently hindered by its high absorption/desorption temperature, and very slow reaction kinetics. one of the approaches to improve the kinetic is $MgH_x$ intermixed with carbon. And it shows that carbon and carbon allotropes have a beneficial effect on hydrogen sorption in Mg. The graphene is a kind of carbon allotropes which is easily desorbed reaction at low temperatures because its reaction is exothermic. In this work, the effect of graphene concentration on the kinetics of Mg hydrogen absorption reaction was investigated. The $MgH_x$-Graphene composites has been prepared by hydrogen induced mechanical alloy (HIMA). The synthesized powder was characterized by XRD and simultaneous TG, DSC analysis. The hydrogenation behaviors were evaluated by using a sievert's type automatic PCT apparatus. In this research, results of kinetic profiles exhibit hydrogen absorption rate of $MgH_x$-5wt.% and 10wt.% graphene composite, as 1.25wt.%/ms, 10.33wt.%/ms against 0.88wt.%/ms for $MgH_x$ alone at 473K.

Evaluation of Hydrogen Properties on Mg2NiHx-Graphene Composites by Mechanical Alloying (기계적 합금화법으로 제조한 Mg2NiHx-Graphene 복합재료의 수소화 특성 평가)

  • Lee, Young-Sang;Lee, Soo-Sun;Lee, Byung-Ha;Jung, Seok;Hong, Tae-Whan
    • Journal of Hydrogen and New Energy
    • /
    • v.25 no.1
    • /
    • pp.19-27
    • /
    • 2014
  • Mg hydride has a high hydrogen capacity (7.6%), at high temperature, and is a lightweight and low cost material, thus it a promising hydrogen storage material. However, its high operation temperature and very slow reaction kinetics are obstacles to practical application. In order to overcome these disadvantages of Mg hydride, graphene powder was added to it. The addition of graphene has been shown to reduce the operating temperature of dehydrogenation. Moreover, in this report the environmental aspects of $MgH_x$-Graphene composites are investigated by means of the environmental life cycle assessment (LCA) method. $MgH_x$-Graphene mixture was prepared by hydrogen induced mechanical alloy (HIMA). The synthesized powder was characterized by XRD(X-ray Diffraction). The hydrogenation behaviors were evaluated by using a Sievert's type automatic PCT apparatus. Such evaluation of Materials also conducted in the LCA. From the result of P-C-T(Pressure-Composition-Temperature) curves, the $MgH_x$-3wt.% graphene composite was evaluated as having a 5.86wt.% maximum hydrogen storage capacity, at 523K. From absorption kinetic testing, the $MgH_x$-7wt.% graphene composite was evaluated as having a maximum 6.94wt.%/ms hydrogen absorption rate, at 573K. Environment evaluation results for the $MgH_x$-graphene composites and other materials indicated environmental impact from the electric power used and from the materials themselves.