Abstract
The present work is focused on the studies of structure, hydrogen storage and electrochemical properties of the La3-xMgxNi9 (x = 1.0, 1.1 and 1.2) alloys as active materials of negative electrodes in the Nickel-Metal Hydride (Ni/MH) batteries. A change of Mg content affects properties of the studied alloys such as the phase homogeneity, hydrogen storage and electrochemical capacities, cycle stability, and high-rate discharge performance. X-ray diffraction study shows that Mg substitution for La and annealing of the La3-xMgxNi9 alloys promotes the formation of more homogeneous materials, with a predominant formation of the target AB3 PuNi3 structure type intermetallics. The electrodes prepared from the annealed alloys show the maximum discharge capacities of ∼400 mAh g−1 at discharge current density of ∼60 mA/g. The high rate discharge-abilities (HRD) at the discharge current density of 350 mA g−1 keep high values of the remaining reversible discharge capacities, ∼86, 85 and 80%, for the La2MgNi9, La1·9Mg1·1Ni9 and La1·8Mg1·2Ni9 alloy electrodes, respectively. After 200 cycles with 100% depth of discharge (DOD), the La1·9Mg1·1Ni9 alloy electrode exhibits a very good cycling stability with its discharge capacity remaining at a level of ∼64% of its initial capacity.
Highlights
Hydrogen energy has a great potential in generating clean power in efficient way and is currently utilized in stationary, portable and transport applications [1,2]
Among various technologies used to store hydrogen, metal hydrides, which were studied and developed during the last 50 years, are recognized as a volume-efficient hydrogen storage technology which is highly suitable for energy storage and conversion systems, when utilized in Ni-MH battery applications [2,3]
A significant research effort has been devoted to the studies of the RE-Mg-Ni alloys for Ni-MH battery applications. 1:3, 2:7 and 5:19 intermetallics all show suitable performance as battery anodes, because their electrochemical discharge capacities of 392 for La2MgNi9, 386 for La3MgNi14 and 367 for La4MgNi19 are superior as compared to 320 mAh/g characteristic for the commercial AB5 type Co-containing alloys [13]
Summary
Hydrogen energy has a great potential in generating clean power in efficient way and is currently utilized in stationary, portable and transport applications [1,2]. Ternary RE-Mg-Ni and RE-Mg-(Ni,Mn) intermetallics crystallizing with the PuNi3 trigonal type of structure were systematically studied as hydrogen storage materials and anode electrode materials for Ni/MH batteries. Effect of substitution of Ni by Co has been studied in a multiphase AB3 type La2MgNi7Co2 alloy This alloy showed an increased hydrogen storage capacity of 1.90 wt% H (@ 10 bar H2) [21]. Hydrogen storage and electrochemical properties of La2MgNi9 alloys were most extensively studied for La2MgNi9 alloy which exhibits superior reversible capacity and a suitable for use in the metal hydride batteries equilibrium pressure of H2 absorptiondesorption The objective is in finding an interrelation between the Mg content and the electrochemical performance of the La3-xMgxNi9 alloys as anodes of the Nickel/Metal Hydride batteries
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