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The effect of different ambient temperatures on the electrochemical properties of La_4MgNi_(17.5)Co_(1.5)hydrogen storage alloy was investigated.The X-ray diffraction pattern shows that the alloy consists of LaNi5-type phase and A_5B_(19)-type(Ce_5Co_(19) + Pr_5Co_(19)) phase.With the increase of the ambient temperature,the maximum discharge capacity of the alloy electrodes increases from 353.33(283 K) to 379.25 mAh/g(308 K),and the cyclic stability(S_(100)) of the electrodes decreases from 80.19(283 K) to 52.04%(308 K) due to the acceleration of pulverization,corrosion and oxidation at higher ambient temperature.Moreover,it is found that the increase of the temperature can accelerate the diffusion rate of hydrogen in the alloy(D) and increase the exchange current density(I_0).which are beneficial for improving the activation performance and the high-rate dischargeability(HRD) of the alloy electrodes.The activation cycles of the electrodes decrease from 4(283 K) to 1(308 K),and the HRD_(900) of the electrodes sharply increases from 66.36(283 K) to 95.64%(308 K).
The effect of different ambient temperatures on the electrochemical properties of La_4MgNi_ (17.5) Co_ (1.5) hydrogen storage alloy was investigated. The X-ray diffraction pattern shows that the alloy consists of LaNi5-type phase and A_5B_type (Ce_5Co_ (19) + Pr_5Co_ (19)) phase.With the increase of ambient temperature, the maximum discharge capacity of the alloy electrode increases from 353.33 (283 K) to 379.25 mAh / g (308 K), and the cyclic stability (100)) of the electrodes decreases from 80.19 (283 K) to 52.04% (308 K) due to the acceleration of pulverization, corrosion and oxidation at higher ambient temperature. Moreover, it is found that the increase of the temperature can accelerate the diffusion rate of hydrogen in the alloy (D) and increase the exchange current density (I_0) .which are beneficial for improving the activation performance and the high-rate dischargeability (HRD) of the alloy electrodes. activation cycles of the electrodes decrease from 4 (283 K) to 1 (308 K), and the HRD _ (900) of the sharp increase in electrodes from 66.36 (283 K) to 95.64% (308 K).