Evaluation of Hydrogenation Kinetics and Life Cycle Assessment on Mg2NiHx–CaO Composites

Magnesium-based alloys are attractive as hydrogen storage materials due to their lightweight and high absorption, but their high operating temperatures and very slow kinetics are obstacles to practical applications. Therefore, the effect of CaO has improved the hydrogenation kinetics and slowed down...

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Veröffentlicht in:	Materials 2021-05, Vol.14 (11), p.2848
Hauptverfasser:	Shin, Hyo-Won, Hwang, June-Hyeon, Kim, Eun-A, Hong, Tae-Whan
Format:	Artikel
Sprache:	eng
Schlagworte:	Absorption Carbon Clean technology Composite materials Emissions Energy Environmental impact Evaluation Fossil fuels Hydrogen Hydrogen storage materials Hydrogenation Impact analysis Inventory Kinetics Life cycle assessment Magnesium base alloys Manufacturing Mathematical analysis Mechanical alloying Methods Operating temperature Raw materials
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description	Magnesium-based alloys are attractive as hydrogen storage materials due to their lightweight and high absorption, but their high operating temperatures and very slow kinetics are obstacles to practical applications. Therefore, the effect of CaO has improved the hydrogenation kinetics and slowed down the degradation. The Mg2NiHx–CaO composites were prepared by hydrogen-induced mechanical alloying (HIMA). Hydrogenation kinetics was performed by using an Automatic PCT Measuring System and evaluated in the temperature range of 423, 523, and 623 K. As a result of calculating the hydrogen absorption amounts through the hydrogenation kinetics curve, they were calculated as about 0.52 wt%, 1.21 wt%, and 1.59 wt% (Mg2NiHx–10 wt% CaO). In this study, the material environmental aspects of Mg2NiHx–CaO composites were investigated through life cycle assessment (LCA). LCA was performed analyzing the environmental impact characteristics of the manufacturing process by using Gabi software and the Eco-Indicator 99’ and Centrum voor Milieuweten schappen (CML 2001) methodology. As a result, the contents of global warming potential (GWP) and fossil fuels were found to have a higher impact than other impact categories.
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subjects	Absorption Carbon Clean technology Composite materials Emissions Energy Environmental impact Evaluation Fossil fuels Hydrogen Hydrogen storage materials Hydrogenation Impact analysis Inventory Kinetics Life cycle assessment Magnesium base alloys Manufacturing Mathematical analysis Mechanical alloying Methods Operating temperature Raw materials
title	Evaluation of Hydrogenation Kinetics and Life Cycle Assessment on Mg2NiHx–CaO Composites
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