High hydrogen storage capacity of nanosized magnesium synthesized by high energy ball-milling

To prepare nanosized magnesium which reversibly absorbs hydrogen with high capacity even under mild conditions, high energy ball-milling of Mg or MgH 2 with benzene or cyclohexane as additives have been studied. In ball-milling of Mg or MgH 2, the use of the organic additives is very crucial in dete...

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Veröffentlicht in:	Journal of alloys and compounds 2005-01, Vol.386 (1), p.211-216
Hauptverfasser:	Imamura, Hayao, Masanari, Kazuo, Kusuhara, Mitsuya, Katsumoto, Hikaru, Sumi, Takeshi, Sakata, Yoshihisa
Format:	Artikel
Sprache:	eng
Schlagworte:	Cross-disciplinary physics: materials science rheology Exact sciences and technology Hydrogen storage materials Materials science Materials synthesis materials processing Mechanical alloying Metals Nanostructures Physics Surfaces and interfaces
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container_title	Journal of alloys and compounds
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creator	Imamura, Hayao Masanari, Kazuo Kusuhara, Mitsuya Katsumoto, Hikaru Sumi, Takeshi Sakata, Yoshihisa
description	To prepare nanosized magnesium which reversibly absorbs hydrogen with high capacity even under mild conditions, high energy ball-milling of Mg or MgH 2 with benzene or cyclohexane as additives have been studied. In ball-milling of Mg or MgH 2, the use of the organic additives is very crucial in determining the characteristics of the resulting nanosized magnesium. Benzene and cyclohexane served to maintain the high-degree dispersion of nanostructured magnesium with small crystallite sizes (9–10 nm) and high surface areas (24–25 m 2 g −1). The behavior of hydrogen absorption by the magnesium was extensively evaluated by differential scanning calorimetry (DSC) measurements and volumetric techniques. The nanosized magnesium prepared by ball-milling of MgH 2 with benzene showed reversible DSC traces for hydriding/dehydriding under 0.1 MPa hydrogen pressure. Moreover, 1 at.% Al-doped or 2.9 at.% Ni-doped nanosized samples obtained by milling of MgH 2 with solutions of Al(C 2H 5) 3 or Ni(C 5H 5) 2 in benzene showed satisfying hydrogen absorption rates, respectively. The reversible hydrogen absorption by the 1 at.% Al-doped sample approximately reached a maximal capacity of 7.3 wt.% even at a 0.1 MPa H 2 atmosphere.
doi_str_mv	10.1016/j.jallcom.2004.04.145
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subjects	Cross-disciplinary physics: materials science rheology Exact sciences and technology Hydrogen storage materials Materials science Materials synthesis materials processing Mechanical alloying Metals Nanostructures Physics Surfaces and interfaces
title	High hydrogen storage capacity of nanosized magnesium synthesized by high energy ball-milling
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