Clean hydrogen production via methane pyrolysis using molten metal alloy catalysts is an interesting approach. However, the high temperatures and dynamic conditions required for pyrolysis render in situ observation of the molten metal system difficult. In this study, we identified two descriptors (H* formation energy and solute metal diffusivity) based on ab initio molecular dynamics simulations to predict the catalytic activity of Bi-based binary alloys (M = Ni, Pt, Cu, Ag) in methane pyrolysis. The solute metals were active sites for strong hydrogen adsorption, whereas solute metal diffusivity determined the extent of its exposure on the surface of the molten metal bubbles. Based on these findings, we identified two ternary alloys (Bi-Ni-Cu and Bi-Ni-Mn) that are catalytically more active than the binary Bi-Ni alloy. This study promotes the theory-based screening of highly active alloy catalysts for methane pyrolysis, thus contributing to the advancement of hydrogen society.
This research was supported by the core KRICT project (KK2411-30) from the Korea Research Institute of Chemical Technology (KRICT), the C1 Gas Refinery Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Science, ICT & Future Planning (NRF-2017M3D3A1A01037001), the H2KOREA funded by the Ministry of Education (2022 Hydrogen fuel cell-002, Innovative Human Resources Development Project for Hydrogen Fuel Cells), and Global Learning & Academic research institution for Master\\u2019s\\u00B7PhD students, and Postdocs (G-LAMP) Program of the NRF grant funded by the Ministry of Education (No. RS-2023-00285390).
