Enhanced hydrogen storage properties of magnesium by the synergic catalytic effect of TiH1.971 and TiH1.5 nanoparticles at room temperature

• The Mg–9.2wt%TiH1.971–3.7wt%TiH1.5 nanocomposite was prepared.
• The Ti hydrides nanoparticles of 13 nm were dispersed on the Mg nanoparticles.
• TiH1.971 and TiH1.5 nanoparticles cooperatively catalyzed the hydrogenation of Mg.
• The nanocomposite absorbed 4.3 wt% H2 in 10 min at room temperature.
• The apparent activation energy for hydrogen absorption was 12.5 kJ mol−1.

In order to improve the hydrogen sorption kinetics of Mg at room temperature, the Mg–9.2wt%TiH1.971–3.7wt%TiH1.5 nanocomposite is successfully prepared by hydrogen plasma-metal reaction (HPMR) method and hydrogenation/dehydrogenation at 673 K. The Mg nanoparticles are hexagonal in shape with the size in the range of 50–190 nm. The spherical Ti hydrides nanoparticles of about 13 nm are uniformly dispersed on the surface of Mg nanoparticles. During hydrogenation/dehydrogenation cycle, the Ti hydrides nanoparticles restrain the growth of Mg nanoparticles. The Mg–TiH1.971–TiH1.5 nanocomposite quickly absorbs 4.3 wt% H2 in 10 min at room temperature and reaches a saturation value of 5.0 wt% in 60 min. The apparent activation energies for hydrogen absorption and desorption are 12.5 and 46.2 kJ mol−1, respectively. The improved kinetics and reduced activation energy are explained in terms of the nanostructure of Mg and the synergic catalytic effect of TiH1.971–TiH1.5 nanoparticles.

The Mg–9.2wt%TiH1.971–3.7wt%TiH1.5 nanocomposite is successfully prepared by hydrogen plasma-metal reaction (HPMR) method and hydrogenation/dehydrogenation at 673 K. The spherical Ti hydrides nanoparticles of about 13 nm are uniformly dispersed on the surface of the Mg nanoparticles. The Mg–TiH1.971–TiH1.5 nanocomposite quickly absorbs 4.3 wt% H2 in 10 min at room temperature and reaches a value of 5.0 wt% in 60 min. The apparent activation energies for hydrogen absorption and desorption are 12.5 and 46.2 kJ mol−1, respectively. The improved kinetics and reduced activation energy are explained in terms of the nanostructure of Mg and the synergic catalytic effect of TiH1.971–TiH1.5 nanoparticles.Figure optionsDownload as PowerPoint slide