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Hydrogen storage performance of LaNi3.95Al0.75Co0.3 alloy with different preparation methods

Lijun Lv, Jian Lin, Yang Guo, Zhaowei Ma, Linhua Xu, Xiujie He, Xingbo Han, Wei Liu

2022Progress in Natural Science Materials International26 citationsDOIOpen Access PDF

Abstract

Rare-earth AB5-type La–Ni–Al hydrogen storage alloys are widely studied due to their extensive application potentials in hydrogen isotope storage, hydrogen isotope isolation and hydrogen compressors, etc. Good hydriding/dehydriding kinetics, easily activation, high reversibility are important factors for their practical application. However, their overall hydrogen storage performance, especially plateau pressure and hydrogen absorption/desorption durability need to be further optimized. In this study, the microstructures and the hydrogen storage properties of as-cast, annealed, and melt-spun LaNi3.95Al0.75Co0.3 alloys were investigated. The experimental results of XRD and SEM showed that all alloys contained a pure CaCu5 type hexagonal structure LaNi4Al phase. The cell volume increased in an order of annealed ​> ​melt-spun ​> ​as-cast, resulting in a lower hydrogen absorption/desorption plateau pressure and a more stable hydride phase. The hydrogen storage capacity of three alloys was almost the same. The slope factor of the annealed and melt-spun alloys is smaller than the as-cast alloy, indicating that heat-treatment process can make the alloys more uniform. For the cycle stability of the alloys, the hydrogen absorption rate of the annealed alloy and melt-spun alloy was much faster than that of the as-cast alloy after 500 cycles. The melt-spun alloy showed high pulverization resistance during hydrogen absorption/desorption, and exhibited an excellent cycling retention of 99% after 500 cycles, suggesting that melt-spinning process can enhance the cycle stability and improve the cycle life of the alloy.

Topics & Concepts

Hydrogen storageMaterials scienceAlloyHydrogenDesorptionMelt spinningHydrideCryo-adsorptionMetallurgyMicrostructureComposite materialSpinningChemistryAdsorptionOrganic chemistryMetalHydrogen Storage and MaterialsAmmonia Synthesis and Nitrogen ReductionHybrid Renewable Energy Systems