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Titanium‒Nickel Dual Active Sites Enabled Reversible Hydrogen Storage of Magnesium at 180 °C with Exceptional Cycle Stability

Haotian Guan, Jiang Liu, Xuan Sun, Yangfan Lu, Hongyuan Wang, Qun Luo, Qian Li, Fusheng Pan

2025Advanced Materials29 citationsDOIOpen Access PDF

Abstract

Abstract Enhancing hydrogenation and dehydrogenation (de/hydrogenation) kinetics without compromising cycle stability is a major challenge for Mg‐based hydrogen storage materials (Mg/MgH 2 ). The de/hydrogenation reactions of Mg/MgH 2 are one of the gas–solid reactions involving hydrogen adsorption, dissociation, diffusion, and nucleation, which often results in the catalysts being unable to simultaneously accelerate these distinct kinetic processes. Here, the Mg 2 Ni@Ti─MgO catalyst with dual active sites is reported to be designed to address this issue. The stabilization of Ti 2+ and Ti 3+ valence states in the MgO lattice simultaneously accelerates hydrogen adsorption and dissociation. Additionally, Mg 2 Ni serves as a hydrogen diffusion and nucleation center, synergistically enhancing de/hydrogenation reactions. Consequently, it enables MgH 2 to release 5.28 wt.% H 2 in 2 min at 280 °C, and achieves 1.96 wt.% H 2 of hydrogen release in 60 min at 180 °C. The Mg 2 Ni@Ti─MgO catalyst exhibits remarkable chemical stability at the interfacial structure, minimizing structural and chemical degradation impact, and realizing excellent de/hydrogenation performance over 1000 cycles. These results provide a new methodology for optimizing multiple kinetic steps, attaining highly efficient and stable de/hydrogenation reactions.

Topics & Concepts

Hydrogen storageDehydrogenationCatalysisMaterials scienceNucleationHydrogenDissociation (chemistry)Chemical engineeringMagnesiumNickelInorganic chemistryAdsorptionChemical stabilityPhysical chemistryChemistryOrganic chemistryMetallurgyEngineeringHydrogen Storage and MaterialsAmmonia Synthesis and Nitrogen ReductionMXene and MAX Phase Materials