Litcius/Paper detail

Vacancy‐Mediated Hydrogen Spillover Improving Hydrogen Storage Properties and Air Stability of Metal Hydrides

Rui Shi, Haoxing Yan, Jiguang Zhang, Haiguang Gao, Yunfeng Zhu, Yana Liu, Xiaohui Hu, Yao Zhang, Liquan Li

2021Small44 citationsDOI

Abstract

Abstract Hydrogen storage in metal hydrides is a promising solution for sustainable and clean energy carriers. Although Mg‐based metal hydrides are considered as potential hydrogen storage media, severe surface passivation has limited their industrial application. In this study, a simple, cheap, and efficient method is proposed to produce highly reactive and air‐stable bulk Mg–Ni‐based hydrides by rapid treatment with water for 3 min. The nickel‐decorated Mg(OH) 2 nanosheets formed in situ during hydrolysis can provide a pathway for hydrogen desorption via vacancy‐mediated hydrogen spillover, as revealed by density functional theory calculations, thereby significantly decreasing the peak dehydrogenation temperature by 108.2 °C. Moreover, water‐activated hydrides can be stored under ambient conditions without surface decay and activity loss, exhibiting excellent air stability, which can be attributed to the chemical stability of the surface layer. The results provide alternative insights into the design of highly active, air‐stable metal hydrides with low cost and promote the industrial application of hydrogen energy.

Topics & Concepts

Hydrogen storageMaterials scienceDehydrogenationHydrogenHydrogen spilloverChemical engineeringPassivationCryo-adsorptionMetalVacancy defectNickelInorganic chemistryDensity functional theoryDesorptionHydrideNanotechnologyMetallurgyAlloyLayer (electronics)CatalysisAdsorptionChemistryOrganic chemistryComputational chemistryCrystallographyEngineeringHydrogen Storage and MaterialsAmmonia Synthesis and Nitrogen ReductionMXene and MAX Phase Materials