Hydrogen-storage characteristics of Cu, Nb2O5, and NbF5-added Mg–Ni alloys

From a Mg–23.5 wt%Ni–5 wt%Cu alloy synthesized by the gravity casting method in a large quantity (7.5 kg), Mg–23.5 wt%Ni–x wt%Cu (x = 2.5, 5 and 7.5) samples for hydrogen storage were prepared by melt spinning and crystallization heat treatment. The samples were ground under H2 in order to obtain a fine powder. These alloys contained crystalline Mg and Mg2Ni phases. The Mg–23.5Ni–2.5Cu alloy had the highest hydriding and dehydriding rates after activation among these alloys. The dehydriding curve under 1.0 bar H2 at 573 K exhibits two stages; the dehydriding rate is high for about 2.5 min (the decomposition of Mg2Ni hydride and Mg hydride in small particles), and then it becomes lower (the decomposition of Mg hydride). The hydriding and dehydriding properties of another sample 88 wt%(87.5Mg–10Ni–2.5Cu)–5 wt%Nb2O5–7 wt%NbF5 were also investigated.

Sample preparation by gravity casting, melt spinning + heat-treatment, and then reactive mechanical grinding.Figure optionsDownload as PowerPoint slideHighlights
► Synthesis of a Mg–23.5 wt%Ni–5 wt%Cu alloy by the gravity casting method in a large quantity (7.5 kg).
► Preparation of Mg–23.5 wt%Ni–x wt%Cu (x = 2.5, 5 and 7.5) samples by melt spinning, heat-treatment, and then grinding under H2.
► Preparation of 88 wt%(87.5 wt%Mg–10 wt%Ni–2.5 wt%Cu)–5 wt%Nb2O5–7 wt%NbF5 sample by milling with nano-sized Nb2O5 and NbF5.
► Investigation of hydrogen-storage properties.