Direct synthesis of Mg(AlH4)2 and CaAlH5 crystalline compounds by ball milling and their potential as hydrogen storage materials

Mg(AlH₄)₂ and CaAlH₅ were synthesized by direct ball milling of AlH₃ and MgH₂ or AlH₃ and CaH₂ hydrides. The XRD profiles indicated crystalline compounds. Several ball-milling conditions were studied and the optimum parameters were found. Among these, the key parameter is the pause used to cool down the milling device, which allows reducing the temperature rise during milling. Thus, the maximum yield of complex hydrides was obtained by minimizing the desorbed alane amount. The decomposition properties were studied and were in agreement with those reported for different synthesis methods. Mg(AlH₄)₂ with a good hydrogen capacity and a decomposition reaction enthalpy close to 0 kJ/mol H₂ can be a candidate for one-way storage systems. As for CaAlH₅, it might be suitable for reversible hydrogen storage thanks to its dehydrogenation reaction enthalpy (26 kJ/mol H₂). However, rather high activation energy values were evaluated for both compounds (119 and 161 kJ/mol, respectively).