Improved kinetic behaviour of Mg(NH(2))(2)-2LiH doped with nanostructured K-modified-Li(x)Ti(y)O(z) for hydrogen storage

The system Mg(NH(2))(2) + 2LiH is considered as an interesting solid-state hydrogen storage material owing to its low thermodynamic stability of ca. 40 kJ/mol H(2) and high gravimetric hydrogen capacity of 5.6 wt.%. However, high kinetic barriers lead to slow absorption/desorption rates even at relatively high temperatures (>180 °C). In this work, we investigate the effects of the addition of K-modified Li(x)Ti(y)O(z) on the absorption/desorption behaviour of the Mg(NH(2))(2) + 2LiH system. In comparison with the pristine Mg(NH(2))(2) + 2LiH, the system containing a tiny amount of nanostructured K-modified Li(x)Ti(y)O(z) shows enhanced absorption/desorption behaviour. The doped material presents a sensibly reduced (∼30 °C) desorption onset temperature, notably shorter hydrogen absorption/desorption times and reversible hydrogen capacity of about 3 wt.% H(2) upon cycling. Studies on the absorption/desorption processes and micro/nanostructural characterizations of the Mg(NH(2))(2) + 2LiH + K-modified Li(x)Ti(y)O(z) system hint to the fact that the presence of in situ formed nanostructure K(2)TiO(3) is the main responsible for the observed improved kinetic behaviour.