Abstract

Magnesium hydride (MgH₂) is regarded as a promising hydrogen storage material owing to its high gravimetric and volumetric capacity and low cost. However, its large-scale application is hampered by high stability leading to elevated temperature and slow kinetics for ab/desorption. To address these problems, herein, a composite having MgH₂ nanoconfined in a 3D nickel single atoms doped porous carbon (MgH₂@3D Ni SA-pC) is successfully prepared. Benefitting from the nondestructive synthetic method, strong coupling between MgH₂ and 3D Ni SA-pC is achieved, and the composite exhibits superior hydrogen sorption performances as compared to blank MgH₂. An onset desorption temperature down to 170?°C and the complete dehydrogenation at 250?°C within 60 min are observed. In particular, thermodynamics of MgH₂ is improved (ΔH_ab = 67.9 kJ mol^?1 H₂) and the heterogenous interfaces are stable during cycling without the formation of an intermetallic Mg₂Ni catalytic phase. Experimental characterizations and theoretical calculations show that the robust interfaces induce charge transfer from Mg/MgH₂ to Ni SA-pC, which contributes to the weakened Mg─H bonds and thereby improves kinetic and even thermodynamics. Such an interface engineering strategy using single-atom Ni catalyst to simultaneously nano-confine and catalyze MgH₂ paves a way to the design of high-performance hydrogen storage materials.