Machine Learning-Accelerated First-Principles Molecular Dynamics Reveals C-C Coupling Mechanisms toward Ethylene on Cu(100)

TMY Yang and WA Saidi, ACS CATALYSIS, 15, 15093-15101 (2025).

DOI: 10.1021/acscatal.5c02726

The Cu(100) termination has been identified as the most effective facet for converting CO and CO2 into ethylene. To enhance both the activity and selectivity of ethylene production, we perform machine-learning- accelerated, first-principles molecular dynamics simulations at 298 K in an explicit solvent at pH 7 to elucidate the C-C coupling mechanism-the critical reaction step in forming C2+ products. Among the six potential C-C coupling pathways, the most feasible are CO* dimerization and CO - CHO* and CHO* - CHO* couplings. Using the computational hydrogen electrode method, we demonstrate that all three pathways are equally accessible at -0.6 V vs RHE. At a potential below -1.0 V vs RHE, the thermodynamic barriers for the CO - CHO* and CHO* - CHO* pathways become negligible. Our computational findings explain the experimental observations, particularly the absence of C2+ products above -0.4 V vs RHE and the peaks in ethylene production near -0.6 and -1.0 V vs RHE. Since CHO* acts as a key intermediate common to both C-C coupling and CH4 formation, we propose that suppressing CHO* hydrogenation would inhibit CH4 pathways, thereby maximizing ethylene selectivity.

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