Theoretical study of the effects of surface Cu coordination environment on CO2 hydrogenation to CH3OH

• Published in: Journal of colloid and interface science Vol. 675; pp. 496 - 504
• Main Authors: Guan, Lifang, Gao, Yuzhao, Li, Chunrong, Wang, He, Zhang, Weiyi, Teng, Botao, Wen, Xiaodong
• Format: Journal Article
• Language: English
• Published: Elsevier Inc 01.12.2024
• Subjects: Coordination environment; Cu facets; DFT; kMC; kMC; DFT; Coordination environment; Cu facets
• ISSN: 0021-9797; 1095-7103; 1095-7103
• DOI: 10.1016/j.jcis.2024.07.058

Insights by DFT and kMC analysis of the effects of Cu coordination environment on CO2 hydrogenation revealed that CO2 hydrogenation to CH3OH predominantly proceeds via HCOO* pathway; and low-coordinated Cu(211) with more openness has higher activity and selectivity of CH3OH. [Display omitted] The coordination environment of Cu (the coordination number and arrangement of surface atoms) plays an important role in CO2 hydrogenation to CH3OH. Compared with the extensive studies of the effects of coordination number, the comprehensive effects of coordination number and arrangement of surface atoms were seldom explored in literature. To unravel the effects of surface Cu coordination environment on CO2 hydrogenation to CH3OH, the adsorption and reaction behaviors of H2 and CO2 on Cu(111), (100), (110) and (211) with different coordination numbers and arrangement of surface Cu were systematically calculated by density functional theory (DFT) and kinetic Monte Carlo (kMC) simulation. It was found that the adsorption energies of intermediates in CO2 hydrogenation on Cu surfaces increase with the decrease of coordination number. When the Cu coordination numbers are similar, the charge density on the open surface derived from the different atom arrangement becomes larger and leads to stronger interaction with intermediates than that on the compact one. DFT calculation and kMC simulation indicate that methanol formation pathway follows CO2*→HCOO*→HCOOH*→H2COOH*→H2CO*→CH3O*→CH3OH* on four Cu facets; CO formation is via CO2 direct dissociation on Cu(111), (100) and (110) but COOH* dissociation on (211). The low-coordinated surface Cu with more openness on Cu(211) is the highly active site for CO2 hydrogenation to CH3OH with high turnover of frequency (3.71 × 10−4 s−1) and high selectivity (87.17 %) at 600 K, PCO2 = 7.5 atm and PH2 = 22.5 atm, which is much higher than those on Cu(111), (100) and (110). This work unravels the effects of coordination environment on CO2 hydrogenation at the molecular level and provides an important insight into the design and development of catalysts with high performance in CO2 hydrogenation to CH3OH.