Improvement of Mg–Al alloys for hydrogen storage applications

In the context of energy carrier, storage of hydrogen is one of the key challenges for research today. The group of Mg-based hydrides stands as a promising candidate for competitive hydrogen storage with high reversible hydrogen capacity. esent studies report encouraging results for Mg–Al system with Nb2O5 additive catalyst. Three nominal compositions [(MgxAl100−x)−99 + (Nb2O5)−1 mol.%], X = 100 (Mg), X = 39 (β-Mg2Al3) and X = 70 (Mg + γ-Mg17Al12) have been investigated for their hydrogen equilibrium pressure of absorption and desorption reactions, from 250 °C to 400 °C. osition of initial Nb2O5 phase was shown after long annealing of samples, with reduction into other oxides. Moreover, the hydrogenation of Mg–Al alloys leads to separate initial phase(s) through several stages with the formation of MgH2 hydride and metallic Al-fcc as the final products. This behavior is clearly visible from multi-plateaux of pressure–composition isotherm curves. case of the X = 70 compound, the reaction was accomplished through three reversible transformation steps. The hydrogen weight capacity of 4.7 wt.% has been found at 250 °C under reproducible conditions.