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Nanocrystalline Mg2Ni for hydrogen storage
Baroutaji, Ahmad Arjunan, Arun Ramadan, Mohamad Alaswad, Abed Achour, Hussam Abdelkareem, Mohammad Ali Olabi, Abdul-Ghani
Baroutaji, Ahmad
Arjunan, Arun
Ramadan, Mohamad
Alaswad, Abed
Achour, Hussam
Abdelkareem, Mohammad Ali
Olabi, Abdul-Ghani
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2020-12-14
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Abstract
Hydrogen continues to receive increased attention as the most promising energy carrier enabling sustainable and eco-friendly energy systems. Despite the various advantages of hydrogen fuel, storing hydrogen in a light-weight and compact form is the barrier towards the commercialization of the hydrogen technologies. Thus, the availability of a reliable, inexpensive, safe and efficient hydrogen storage technology is crucial to support and foster the transition to a hydrogen-powered world. Among the possible hydrogen storage solutions, storing hydrogen in the solid-state, such as metal hydrides, is the safest and most attractive method for on-board hydrogen storage. The metal hydrides can release highly pure hydrogen, via a low-pressure endothermic process, suitable to be used directly in the hydrogen fuel cell devices. This article presents an overview of using Mg and Mg2Ni-based alloys for solid-state hydrogen storage. A review of the hydrogen storage technologies is presented first and then the most recent developments on Mg and Mg2Ni-based hydrogen storage materials are highlighted.
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Baroutaji, A., Arjunan, A., Ramadan, M., Alaswad, A., Achour, H., Abdelkareem, M.A. and Olabi, A. (2021) Nanocrystalline Mg2Ni for hydrogen storage. Reference Module in Materials Science and Materials Engineering 2021.
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This is an accepted manuscript of an article published byElsevier in Reference Module in Materials Science and Materials Engineering on 14/12/2020, available online: https://doi.org/10.1016/B978-0-12-815732-9.00061-9
The accepted version of the publication may differ from the final published version