Some physical aspects of hydrogen behaviour in the H-Storage bcc alloys Ti35VxCr65−x, Ti40VxMn50−xCr10 and TixCr97.5−xMo2.5

Hydrogen absorption/desorption has been investigated in the three series of solid solution bcc alloys Ti₃₅V_xCr_65−x (x = 18,22), Ti₄₀V_xMn_50−xCr₁₀ (x = 32,36) and Ti_xCr_97.5−xMo_2.5 (x = 43,46). It has been found that the H absorption at pressures smaller than 1 bar can only occur after elimination of the oxide films by heating the alloys to temperatures higher than 600 K. Hydrogen desorption from pre-loaded materials (n_H = H/Me ≤ 0.27) takes place on heating at much lower temperatures in the Ti₄₀V_xMn_50−xCr₁₀ and Ti₃₅V_xCr_65−x than in the Ti_xCr_97.5−xMo_2.5 alloys. The H diffusion parameters W and D_o deduced from high temperature (>450 K) absorption experiments are as follows: W = 0.318 ± 0.005 eV, D_o = (4 ± 1)×10⁻⁷ m²/s for Ti₄₀V_xMn_50−xCr₁₀; W = 0.32 ± 0.02 eV, D_o = (3 ± 2)×10⁻⁷ m²/s for Ti₃₅V_xCr_65−x; W = 0.79 ± 0.06 eV, D_o = (4 ± 2)×10⁻⁸ m²/s for Ti_xCr_97.5−xMo_2.5. The higher value of the activation energy for H diffusion in Mo containing alloys is most likely due to remarkable attractive interactions between H and Mo atoms.