Abstract

In order to elucidate the effects of metallic La addition on the performance of Ti–V-based hydrogen storage alloys as negative electrodes for nickel/metal-hydrides batteries, Ti 0.17 Zr 0.08- x La x V 0.35 Cr 0.1 Ni 0.3 ( x = 0, 0.01, 0.02, 0.03, 0.04) alloys were prepared and their structural and electrochemical properties were systematically investigated. X-ray powder diffraction (XRD) results showed that these alloys were mainly consisted of C14 Laves phase with a hexagonal structure, V-based solid solution phase with BCC structure and C15 Laves phase with a cubic structure. The electrochemical measurements indicated that the maximum discharge capacities of the alloy electrodes decreased from 337.3 mAh/g ( x = 0) to 262.5 mAh/g ( x = 0.04) and that the substitution of Zr with metallic La in the alloys had no obvious effect on the capacity retention rate ( C 100 / C max , C 200 / C max ). The high-rate dischargeability ( HRD ) of the alloy electrodes at the discharge current density of 800 mA/g first increased from 69.01% ( x = 0) to 71.13% ( x = 0.01) and then decreased to 65.35% ( x = 0.04). In brief, the HRD was improved with an optimum La content in the alloy ( x = 0.01). The electrochemical hydrogen kinetics of the alloy electrodes was further studied by means of electrochemical impedance spectroscopy, linear polarization, anodic polarization and potential-step measurements. The charge-transfer reaction resistance R ct decreased for x = 0.01 with respect to x = 0 and then increased with the increase of x , while exchange current density I 0 , limiting current density I L and hydrogen diffusion coefficient D were all increased for x = 0.01 with respect to x = 0 and then decreased with the increase of x . The optimal content of La in Ti 0.17 Zr 0.08- x La x V 0.35 Cr 0.1 Ni 0.3 alloys for negative electrodes in alkaline rechargeable secondary batteries is x = 0.01 in this study.

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