Assessment of the Degradation Mechanisms of Cu Electrodes during the CO 2 Reduction Reaction.
Rik Valentijn MomLuis-Ernesto Sandoval-DiazDunfeng GaoCheng-Hao ChuangEmilia A CarbonioTravis E JonesRosa ArrigoDanail IvanovMichael HäveckerBeatriz Roldan CuenyaRobert SchlöglThomas LunkenbeinAxel Knop-GerickeJuan-Jesus Velasco-VelezPublished in: ACS applied materials & interfaces (2023)
Catalyst degradation and product selectivity changes are two of the key challenges in the electrochemical reduction of CO 2 on copper electrodes. Yet, these aspects are often overlooked. Here, we combine in situ X-ray spectroscopy, in situ electron microscopy, and ex situ characterization techniques to follow the long-term evolution of the catalyst morphology, electronic structure, surface composition, activity, and product selectivity of Cu nanosized crystals during the CO 2 reduction reaction. We found no changes in the electronic structure of the electrode under cathodic potentiostatic control over time, nor was there any build-up of contaminants. In contrast, the electrode morphology is modified by prolonged CO 2 electroreduction, which transforms the initially faceted Cu particles into a rough/rounded structure. In conjunction with these morphological changes, the current increases and the selectivity changes from value-added hydrocarbons to less valuable side reaction products, i.e. , hydrogen and CO. Hence, our results suggest that the stabilization of a faceted Cu morphology is pivotal for ensuring optimal long-term performance in the selective reduction of CO 2 into hydrocarbons and oxygenated products.
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