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Single-Atom Ni Supported on TiO<sub>2</sub> for Catalyzing Hydrogen Storage in MgH<sub>2</sub>

Jiyue Zhang, Wenda Wang, Xiaowei Chen, Jinlong Jin, Xiaojun Yan, Jianmei Huang

2024Journal of the American Chemical Society168 citationsDOI

Abstract

As an efficient and clean energy carrier, hydrogen is expected to play a key role in future energy systems. However, hydrogen-storage technology must be safe with a high hydrogen-storage density, which is difficult to achieve. MgH 2 is a promising solid-state hydrogen-storage material owing to its large hydrogen-storage capacity (7.6 wt %) and excellent reversibility, but its large-scale utilization is restricted by slow hydrogen-desorption kinetics. Although catalysts can improve the hydrogen-storage kinetics of MgH 2, they reduce the hydrogen-storage capacity. Single-atom catalysts maximize the atom utilization ratio and the number of interfacial sites to boost the catalytic activity, while easy aggregation at high temperatures limits further application. Herein, we designed a single-atom Ni-loaded TiO 2 catalyst with superior thermal stability and catalytic activity. The optimized 15wt%-Ni 0.034 @TiO 2 catalyst reduced the onset dehydrogenation temperature of MgH 2 to 200 °C. At 300 °C, the H 2 released and absorbed 4.6 wt % within 5 min and 6.53 wt % within 10 s, respectively. The apparent activation energies of MgH 2 dehydrogenation and hydrogenation were reduced to 64.35 and 35.17 kJ/mol of H 2, respectively. Even after 100 cycles of hydrogenation and dehydrogenation, there was still a capacity retention rate of 97.26%. The superior catalytic effect is attributed to the highly synergistic catalytic activity of single-atom Ni, numerous oxygen vacancies, and multivalent Ti x+ in the TiO 2 support, in which the single-atom Ni plays the dominant role, accelerating electron transfer between Mg 2+ and H – and weakening the Mg–H bonds. This work paves the way for superior hydrogen-storage materials for practical unitization and also extends the application of single-atom catalysis in high-temperature solid-state reactions.

Topics & Concepts

DehydrogenationHydrogen storageCatalysisChemistryHydrogenDesorptionKineticsActivation energyAtom (system on chip)Chemical engineeringPhysical chemistryOrganic chemistryAdsorptionEngineeringComputer scienceQuantum mechanicsEmbedded systemPhysicsHydrogen Storage and MaterialsHybrid Renewable Energy SystemsAmmonia Synthesis and Nitrogen Reduction
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