Wide band gap metal oxide semiconductor catalysts mostly exhibit very huge variations of catalytic reaction activities and pathways depending on the preparation conditions, unlike metallic catalyst materials. Atomic-scale modeling and ab initio calculations are extremely challenging for metal oxide semiconductor catalysts because of two main reasons: (i) large discrepancies between computational predictions and experiments, (ii) typical cell size limitations in modeling for dilute level doping (<1020 cm−3) cocatalyst size-dependency (diameter >3 nm). In this study, as a new groundbreaking methodology, we used a combination of density functional theory (DFT) calculations and a newly derived analytical model to systematically investigate the mechanisms of catalytic methane (CH4) oxidation activity change of CeO2. The key hypothesis that the catalytic methane oxidation reaction can be followed by the Fermi level change in CeO2 was well demonstrated via comparison with our multi-scale simulation and several literature reports. Our new method was found to give predictions in the catalytic activity of wide band gap semiconductors for variations in defect concentrations and cocatalyst coverage with advanced efficiency and accuracy, overcoming the typical model size limitation and inaccuracy problems of DFT calculations.
This research was supported by the National R&D Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Science and ICT (RS-2023-00209910, RS-2023-00285390, RS-2024-00444182 and RS-2024-00407282) and Virtual Engineering Platform Project through the Ministry of Trade, Industry, and Energy of Korea (P0022336). We acknowledge the grant no. 2021-0-02076 and 2023-00262155 (IITP) funded by the Korea government (the Ministry of Science and ICT). D. Li is thankful for the support through the Research Development Fund by Xi'an Jiaotong-Liverpool University. H. Choi acknowledges the financial support received through an Enhancement Fund (AY23/24) from the School of Science at Xi'an Jiaotong-Liverpool University. We acknowledge and are thankful for the support received from the Suzhou Industrial Park High Quality Innovation Platform of Functional Molecular Materials and Devices (YZCXPT2023105) and the XJTLU Advanced Materials Research Center (AMRC).
