Microscopic Transformations of Electrocatalyst Surfaces
An important building block in achieving climate targets is to develop technologies that can produce synthetic fuels and chemical feedstocks from CO2 using electricity from renewable sources. In the electrochemical conversion of CO2, defect structures on catalyst surfaces are believed to have a significant impact on selectivity. Researchers at Kiel University (CAU) and the Department of Interface Science at the Fritz Haber Institute of the Max Planck Society have now shown that atomic rearrangements occur even in the early stages of the reaction.
Developing technologies that can convert CO2 into synthetic fuels and base chemicals is of key importance for reaching the climate goals. The electrochemical reduction of CO2 at copper electrodes allows to do this directly with electric power from renewable sources which could be used for the production of e-fuels. New studies show that this process changes the arrangement of the copper atoms at the catalyst surface.
Copper is an indispensable catalyst material for CO2 reduction, especially for the synthesis of particular valuable chemicals and fuels, such as ethanol. For this, it is highly favorable, if the copper atoms at the surface have a strongly disordered arrangement. The latter can be achieved for example by pre-oxidizing the copper surface or through alloying. In a joint study of the Institute of Experimental and Applied Physics of Kiel University and the Department of Interface Science at the Fritz Haber Institute (FHI) of the Max Planck Society (MPG) such disordered structures turned out to form also spontaneously in the very initial stages of the electrocatalytic CO2 reduction reaction. The researchers observed that copper atoms inside the metal moved towards the surface and assembled into a freestanding group of only a few atoms. This transformation of the metal was caused by CO, an intermediate product of the reaction, and was preserved even at high reaction rates. The results were published today in the renowned scientific journal Nature Catalysis.
“Because the electrocatalytic CO2 reduction occurs at metals in aqueous carbonate solution similar to mineral water, and is accompanied by the formation of hydrogen gas, detailed investigations of the process on the atomic scale is difficult”, says Olaf Magnussen, Professor for Solid State Physics at Kiel University.
The researchers therefore used a combination of methods that can be employed even under these challenging conditions. The team from Kiel observed the transformation of the copper surface directly by high-resolution electrochemical scanning tunneling microscopy (see Figure 1). This method allows direct imaging of the atoms and molecules at the surface. X-ray diffraction studies, performed by scientists from Kiel and Berlin at the PETRA III synchrotron of DESY in Hamburg confirmed this transformation. In addition, these measurements showed that at high reaction rates the freestanding copper atoms were maintained, but no further formation occurred. Molecular spectroscopy at the Fritz Haber Institute finally indicated that the changes were induced by the formed CO.
“The results suggest a drastic transformation of the electrode surface each time that the electric potential required for the CO2 reduction is switched on. This was previously unknown, but could play an important role in catalysis”, says Professor Beatriz Roldán Cuenya, Director of the Interface Science Department at FHI. One strategy to influence the structure of the catalyst and thus the type of formed chemical compounds is to operate the electrode with voltage pulses. Indeed, this had been shown already in previous work of the research team. However, the copper there was periodically oxidised by means of electrical energy, which requires the polarity of the electrode to be reversed. According to the new results, similar effects might be obtained already by simply switching the current on and off. “Overall, the study confirms our hypothesis that not only the electrode material but also the operating conditions and micro-environment are relevant for the realization of this environmentally friendly technology”, says the team.
