Hydrogenation and microstructural study of melt-spun Ti0.8V0.2

“…Regardless of the production method, the alloy had two-phase structure and consisted of a Laves phase of type C14 and b.c.c.-solid solution. The authors noted that the homogeneity of the elements' distribution in the phases of the alloy after induction melting is much higher, which correlated with the data obtained in [15]. The authors of [14] claimed that the best performance of the hydrogenation process is obtained at a temperature of 150°C, with hydrogen absorption by the cast alloy at a level of 2% wt., whereas in the case of mechanical alloying it is only 1.2% wt.…”

Hydrogen Storage Properties of Ti$_{15.4}$Zr$_{30.2}$Mn$_{44}$V$_{5.4}$Сr$_5$ Alloy Produced by Induction and Arc Melting

“…Regardless of the production method, the alloy had two-phase structure and consisted of a Laves phase of type C14 and b.c.c.-solid solution. The authors noted that the homogeneity of the elements' distribution in the phases of the alloy after induction melting is much higher, which correlated with the data obtained in [15]. The authors of [14] claimed that the best performance of the hydrogenation process is obtained at a temperature of 150°C, with hydrogen absorption by the cast alloy at a level of 2% wt., whereas in the case of mechanical alloying it is only 1.2% wt.…”

Hydrogen Storage Properties of Ti$_{15.4}$Zr$_{30.2}$Mn$_{44}$V$_{5.4}$Сr$_5$ Alloy Produced by Induction and Arc Melting

Microstructure and Hydrogen Absorption Properties of a BCC Phase Accompanied Laves Alloy

Hydrogen storage properties of non-stoichiometric Zr0.9Ti V2 melt-spun ribbons