Recently, Dr. Yaguang Li et al. at Research Center for Solar Driven Carbon Neutrality find that Ni single-atomization can improve the NH₃ cracking to hydrogen activity, which is coupled with a photothermal system to successfully achieve highly efficient solar-thermal ammonia cracking to hydrogen. The related work, "Low Temperature Thermal and Solar Heating Carbon-Free Hydrogen Production from Ammonia Using Nickel Single Atom Catalysts," is published in Advanced Energy Materials (IF=29.698, 2022, 2202459) with Hebei University as the main research institution. Dr. Li Yaguang is the first and corresponding author of the paper, and Dr. Zhang Zhibo and Professor Ye Jinhua are co-corresponding authors.

Catalytic ammonia decomposition hydrogen production is one of the fundamental technologies for constructing a zero-carbon hydrogen energy system, with non-precious metal materials such as nickel being the main catalysts for ammonia decomposition hydrogen production. Although various non-precious metal catalysts have been designed, their NH₃ decomposition hydrogen production reaction still requires high temperatures (600-850°C), hindering the widespread application of ammonia decomposition hydrogen production. This work predictes from theoretical calculations that nickel single atoms can change the bonding pattern of nickel catalysts with NH₃, thus improving the NH₃ cracking activity of nickel catalysts. Based on the theoretical results, the research team synthesizes Ni single-atom/CeO₂ two-dimensional material (SA Ni/CeO₂) via the sol-gel method, demonstrating excellent NH₃ catalytic decomposition performance at a low temperature of 300°C. The H₂ production rate of 3.544 mmol g^-1min^-1 is better than all non-precious metal catalysts and most precious metal catalysts. When combine with the custom photothermal device developed by the research group, under standard sunlight, the NH₃ catalytic decomposition hydrogen production rate of SA Ni/CeO₂ reaches 1.58 mmol g^-1 min^-1, which is more than 100 times the reported natural sunlight-driven NH₃ catalytic decomposition hydrogen production record rate, showing potential for practical application in zero-carbon hydrogen energy systems.

The above work was supported by the Hebei Provincial Natural Science Foundation, Hebei Provincial Department of Science and Technology, Hebei Provincial Department of Education, Hebei University Institute of Life Sciences and Green Development, Hebei University Multidisciplinary Natural Science Research Project, Hokkaido University's Photons Project, Guangdong Academy of Sciences, the State Key Laboratory of Catalysis, and the strong support of the Hebei University School of Physics Public Testing Center.

Low Temperature Thermal and Solar Heating Carbon-Free Hydrogen Production from Ammonia Using Nickel Single Atom Catalysts.pdf

Link:https://doi.org/10.1002/aenm.202202459