CO₂ reduction on pure Cu produces only H₂ after subsurface O is depleted: Theory and experiment
Guiji Liu, Michelle Lee, Soonho Kwon, Guosong Zeng, Johanna Eichhorn, Aya K. Buckley, F. Dean Toste, William A. Goddard III, Francesca M. Toma
Abstract
We elucidate the role of subsurface oxygen on the production of C₂ products from CO₂ reduction over Cu electrocatalysts using the newly developed grand canonical potential kinetics density functional theory method, which predicts that the rate of C₂ production on pure Cu with no O is ∼500 times slower than H₂ evolution. In contrast, starting with Cu₂O, the rate of C₂ production is >5,000 times faster than pure Cu(111) and comparable to H₂ production. To validate these predictions experimentally, we combined time-dependent product detection with multiple characterization techniques to show that ethylene production decreases substantially with time and that a sufficiently prolonged reaction time (up to 20 h) leads only to H₂ evolution with ethylene production ∼1,000 times slower, in agreement with theory. This result shows that maintaining substantial subsurface oxygen is essential for long-term C₂ production with Cu catalysts.
Group Members
Liu, G., Lee, M., Kwon, S., Zeng, G., Eichhorn, J., Buckley, A. K., Toste, F. D., III, W. A. G., & Toma, F. M. (2021). CO₂ reduction on pure Cu produces only H₂ after subsurface O is depleted: Theory and experiment. *Proc. Natl. Acad. Sci. U.S.A.*, *118*(23), Art. No. e2012649118. https://doi.org/10.1073/pnas.2012649118