Abstract:The partial substitution of M (M=Sm, Nd, Pr) for La was performed in order to ameliorate the electrochemical hydrogen storage performance of RE–Mg–Ni-based A₂B₇-type electrode alloys. The La_0.8–xM_xMg_0.2Ni_3.35Al_0.1Si_0.05 (M=Sm, Nd, Pr; x=0-0.4) electrode alloys were fabricated by casting and annealing and their microstructures were characterized by X-ray diffraction (XRD) and scanning electron microscopy (SEM). The major phases (La, Mg)₂Ni₇ with the hexagonal Ce₂Ni₇-type structure and LaNi₅ with the hexagonal CaCu₅-type structure make up the basic microstructure of the experimental alloys. The discharge capacities of the as-cast and annealed alloys all gain their maximum values with the M (M=Sm, Nd, Pr) content varying. The electrochemical cycle stability of the as-cast and annealed alloys clearly rises with the M (M=Sm, Nd, Pr) content growing. Furthermore, the electrochemical kinetics of the alloys, including the high rate discharge ability, charge transfer rate, limiting current density and hydrogen diffusion coefficient, all present a increase trend at first and then decrease with the rising of M (M=Sm, Nd, Pr) content.

Key words: hydrogen storage; elements substitution; microstructure; electrochemical performance