Structural analysis of calcium reactive hydride composite for solid state hydrogen storage

Owing to a theoretical hydrogen storage capacity of 10.5 wt% H₂, Ca(BH₄)₂+MgH₂, the so-called calcium reactive hydride composite (Ca-RHC), has a great potential as a hydrogen storage material. However, its dehydrogenation temperature (∼623 K) is too high for any mobile applications. By addition of 10 mol% of NbF₅ into Ca(BH₄)₂+MgH₂, a decrease of the dehydrogenation onset temperature by ∼120 K is observed. In order to understand the reasons behind this desorption temperature decrement two sets of samples [Ca(BH₄)₂+MgH₂ and Ca(BH₄)₂+MgH₂+0.1NbF₅] in different hydrogenation states, were prepared. The structural investigation of the above mentioned sets of samples by means of volumetric measurements, anomalous small-angle X-ray scattering (ASAXS) and X-ray absorption spectroscopy (XAS) is reported here. The XAS results show that after the milling procedure NbB₂ is formed and remains stable upon further de/rehydrogenation cycling. The results of Nb ASAXS point to nanometric spherical NbB₂ particles distributed in the hydride matrix, with a mean diameter of ∼10 nm. Results from Ca ASAXS indicate Ca-containing nanostructures in the Ca-RHC+0.1NbF₅ samples to be ∼50% finer compared to those without additive. Thus, a higher reaction surface area and shorter diffusion paths for the constituents are concluded to be important contributions to the catalytic effect of an NbF₅ additive on the hydrogen sorption kinetics of the Ca(BH₄)₂+MgH₂ composite system.