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DFT Study of Metal-Hydrogen Systems for Hydrogen Storage. / Shelyapina, Marina.

Advances in Materials Science Research. ed. / M.C. Wythers. Vol. 23 Nova Science Publishers, Inc., 2016. p. 185-206.

Research output: Chapter in Book/Report/Conference proceedingChapterResearchpeer-review

Harvard

Shelyapina, M 2016, DFT Study of Metal-Hydrogen Systems for Hydrogen Storage. in MC Wythers (ed.), Advances in Materials Science Research. vol. 23, Nova Science Publishers, Inc., pp. 185-206.

APA

Shelyapina, M. (2016). DFT Study of Metal-Hydrogen Systems for Hydrogen Storage. In M. C. Wythers (Ed.), Advances in Materials Science Research (Vol. 23, pp. 185-206). Nova Science Publishers, Inc..

Vancouver

Shelyapina M. DFT Study of Metal-Hydrogen Systems for Hydrogen Storage. In Wythers MC, editor, Advances in Materials Science Research. Vol. 23. Nova Science Publishers, Inc. 2016. p. 185-206

Author

Shelyapina, Marina. / DFT Study of Metal-Hydrogen Systems for Hydrogen Storage. Advances in Materials Science Research. editor / M.C. Wythers. Vol. 23 Nova Science Publishers, Inc., 2016. pp. 185-206

BibTeX

@inbook{494c479e7e3945bf8b643a134b9a98dd,
title = "DFT Study of Metal-Hydrogen Systems for Hydrogen Storage",
abstract = "Hydrogen storage is a key point for the extensive use of hydrogen as an energy carrier. The safest way to store hydrogen is in solid metal hydrides, from which it can be recovered by heating. To be economically feasible the metal or alloy used for hydrogen storage has to exhibit high hydrogen storage capacity, low temperature of the hydrogen release and be low cost. Unfortunately among many metals and alloys reacting with hydrogen there is no such a material that meets all the necessary criteria. Despite low hydrogen sorption kinetics and high stability magnesium is one of the most perspective materials for hydrogen storage. Numerous attempts have been made in order to improve its hydrogen absorbing-desorbing characteristics by alloying with transition metals and their alloys, such as Ti-V-Cr, micro- and nanostructuring and so on. But the fundamental issues of the impact, sometimes rather dramatic, of such modifications of Mg on its stability and hydrogen sorption kinetics are not completely understood. Densi",
author = "Marina Shelyapina",
year = "2016",
language = "English",
isbn = "978-1-63484-484-0",
volume = "23",
pages = "185--206",
editor = "Wythers, {M.C. }",
booktitle = "Advances in Materials Science Research",
publisher = "Nova Science Publishers, Inc.",
address = "United States",

}

RIS

TY - CHAP

T1 - DFT Study of Metal-Hydrogen Systems for Hydrogen Storage

AU - Shelyapina, Marina

PY - 2016

Y1 - 2016

N2 - Hydrogen storage is a key point for the extensive use of hydrogen as an energy carrier. The safest way to store hydrogen is in solid metal hydrides, from which it can be recovered by heating. To be economically feasible the metal or alloy used for hydrogen storage has to exhibit high hydrogen storage capacity, low temperature of the hydrogen release and be low cost. Unfortunately among many metals and alloys reacting with hydrogen there is no such a material that meets all the necessary criteria. Despite low hydrogen sorption kinetics and high stability magnesium is one of the most perspective materials for hydrogen storage. Numerous attempts have been made in order to improve its hydrogen absorbing-desorbing characteristics by alloying with transition metals and their alloys, such as Ti-V-Cr, micro- and nanostructuring and so on. But the fundamental issues of the impact, sometimes rather dramatic, of such modifications of Mg on its stability and hydrogen sorption kinetics are not completely understood. Densi

AB - Hydrogen storage is a key point for the extensive use of hydrogen as an energy carrier. The safest way to store hydrogen is in solid metal hydrides, from which it can be recovered by heating. To be economically feasible the metal or alloy used for hydrogen storage has to exhibit high hydrogen storage capacity, low temperature of the hydrogen release and be low cost. Unfortunately among many metals and alloys reacting with hydrogen there is no such a material that meets all the necessary criteria. Despite low hydrogen sorption kinetics and high stability magnesium is one of the most perspective materials for hydrogen storage. Numerous attempts have been made in order to improve its hydrogen absorbing-desorbing characteristics by alloying with transition metals and their alloys, such as Ti-V-Cr, micro- and nanostructuring and so on. But the fundamental issues of the impact, sometimes rather dramatic, of such modifications of Mg on its stability and hydrogen sorption kinetics are not completely understood. Densi

UR - https://www.novapublishers.com/catalog/product_info.php?products_id=57059

M3 - Chapter

SN - 978-1-63484-484-0

VL - 23

SP - 185

EP - 206

BT - Advances in Materials Science Research

A2 - Wythers, M.C.

PB - Nova Science Publishers, Inc.

ER -

ID: 7557872