AI Article Synopsis
- The study investigates how copper (Cu) catalysts change structurally during the electrochemical reduction of carbon monoxide (CO), using advanced techniques like electron microscopy and molecular dynamics simulations.
- It finds that the presence of alkali cations in the electrolyte is crucial because they trigger a process called cathodic corrosion that leads to significant changes in the Cu catalysts when the electrode potential is more negative than a specific value.
- While these structural changes do not completely stop the effectiveness of the electrocatalytic process, they can hinder long-term performance and stability, suggesting that operating at less negative potentials can yield better consistency in selectivity for Cu nanocubes compared to spherical nanoparticles.
Article Abstract
The reconstruction of Cu catalysts during electrochemical reduction of CO is a widely known but poorly understood phenomenon. Herein, we examine the structural evolution of Cu nanocubes under CO reduction reaction and its relevant reaction conditions using identical location transmission electron microscopy, cyclic voltammetry, in situ X-ray absorption fine structure spectroscopy and ab initio molecular dynamics simulation. Our results suggest that Cu catalysts reconstruct via a hitherto unexplored yet critical pathway - alkali cation-induced cathodic corrosion, when the electrode potential is more negative than an onset value (e.g., -0.4 V when using 0.1 M KHCO). Having alkali cations in the electrolyte is critical for such a process. Consequently, Cu catalysts will inevitably undergo surface reconstructions during a typical process of CO reduction reaction, resulting in dynamic catalyst morphologies. While having these reconstructions does not necessarily preclude stable electrocatalytic reactions, they will indeed prohibit long-term selectivity and activity enhancement by controlling the morphology of Cu pre-catalysts. Alternatively, by operating Cu catalysts at less negative potentials in the CO electrochemical reduction, we show that Cu nanocubes can provide a much more stable selectivity advantage over spherical Cu nanoparticles.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11176167 | PMC |
| http://dx.doi.org/10.1038/s41467-024-49492-7 | DOI Listing |
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Article Synopsis
- The study investigates how copper (Cu) catalysts change structurally during the electrochemical reduction of carbon monoxide (CO), using advanced techniques like electron microscopy and molecular dynamics simulations.
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- While these structural changes do not completely stop the effectiveness of the electrocatalytic process, they can hinder long-term performance and stability, suggesting that operating at less negative potentials can yield better consistency in selectivity for Cu nanocubes compared to spherical nanoparticles.
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