Metallic glassy Ti 2 Ni grain-growth inhibitor powder for enhancing the hydrogenation/dehydrogenation kinetics of MgH 2 .

Because of its high thermal stability and poor hydrogenation/dehydrogenation kinetics, magnesium hydride (MgH 2 ) requires mechanical treatment and/or doping with catalytic agents(s) to understand the decomposition temperature and accelerate the gas uptake/release kinetics. Whereas all catalytic species used for this purpose are crystalline materials, in this paper use of titanium nickel (Ti 2 Ni) metallic glassy (MG) nanopowders for enhancing the hydrogenation/dehydrogenation kinetics behavior of MgH 2 powders is reported. In the present research, MG-Ti 2 Ni ribbons, prepared using a melt spinning technique were snipped into small pieces and then cryo-milled under a flow of liquid nitrogen to obtain submicron-powders (500 nm). The as-prepared MgH 2 powders were doped with 10 wt% of the glassy powder and then cryo-milled for 25 h. The structural and morphological analysis indicated that the cryo-milling process succeeded in maintaining the short-range order structure of MG-Ti 2 Ni, and in reducing the MgH 2 grain size to the nanolevel. The results showed that the as-prepared nanocomposite powders obtained after 25 h of cryo-milling decomposed at 283 °C, with an apparent activation energy of 87.3 kJ mol -1 . The MgH 2 /10 wt% MG-Ti 2 Ni nanocomposite powders were cold rolled into thin strips, using a cold rolling technique. These cold rolled strips possessed excellent morphological characteristics, shown by the homogeneous distribution of the MgH 2 spherical particles (10 nm in diameter) in the glassy Ti 2 Ni matrix. Furthermore, the hydrogenation/dehydrogenation kinetics measured at 225 °C were very fast, as indicated by the short time (400 s) required to uptake/release 5.7 wt% H 2 . At this temperature, the system possessed good life-time cycling performance - achieving 84 continuous cycles within 30 h without failure or degradation.