Characterisation of Mg–x wt.% FeTi (x = 5–30) and Mg–40 wt.% FeTiMn hydrogen absorbing materials prepared by mechanical alloying

Composites based on Mg with intermetallic FeTi (up to 30wt.%) and FeTiMn (40wt.%) were prepared by mechanical alloying for evaluation of their hydrogen storage characteristics. In the first case FeTi was prepared by mechanical alloying and subsequently milled with Mg under argon in different proport...

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Bibliographic Details
Published in:Journal of alloys and compounds 2004-12, Vol.384 (1-2), p.283-295
Main Authors: Vijay, R., Sundaresan, R., Maiya, M.P., Srinivasa Murthy, S., Fu, Y., Klein, H.-P., Groll, M.
Format: Article
Language:English
Subjects:
Cross-disciplinary physics: materials science
rheology
Exact sciences and technology
High-energy ball milling
Hydrogen storage materials
Materials science
Materials synthesis
materials processing
Physics
Scanning electron microscopy
X-ray diffraction
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Summary:Composites based on Mg with intermetallic FeTi (up to 30wt.%) and FeTiMn (40wt.%) were prepared by mechanical alloying for evaluation of their hydrogen storage characteristics. In the first case FeTi was prepared by mechanical alloying and subsequently milled with Mg under argon in different proportions. Powders milled under argon had to be activated by remilling under hydrogen. In the second case FeTiMn prepared by melting was milled together with MgH2 under hydrogen. Hydrogen storage characteristics, pressure-composition isotherms and kinetics were investigated under different parameters. Among the FeTi composites, Mg–5wt.% FeTi had the maximum absorption capacity of 5.80wt.% at 300°C and 5.12wt.% at 200°C. At 300°C the initial desorption rate was the highest for Mg–10wt.% FeTi, but its final desorption capacity was less than that of Mg–5wt.% FeTi. None of the compositions showed any desorption at 200°C. In the case of composites with FeTiMn, absorption and desorption temperatures decreased by ball milling and higher storage capacities were achieved. In Mg–40wt.% FeTiMn, the lowest absorption and desorption temperatures were 80 and 240°C, respectively, with the material absorbing 4wt.% hydrogen even at 80°C. The kinetics improved with increasing milling time.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2004.04.115