Innovative study from the Fritz Baber Institute unveils a new path in green chemistry

The core of this discovery lies in intriguing properties of catalysts composed of ultradispersed copper and nitrogen atoms incorporated into carbon. During the electrocatalytic CO₂ reduction (CO₂RR) process, which is a process used to transform CO₂ into useful chemicals, these catalysts can dynamically change from having copper in the form of single atoms to forming small clusters and metal particles, known as nanoparticles, and then back again, once the applied electrical potential is lifted or changed to a more positive value This control over this reversible transformation provides a  key for steering the structure of the catalyst, and, consequently, controlling the outcome of the CO₂RR process, since the product selectivity strongly depends on the catalyst structure.

The Significance of the Findings

The ability to control the size and structure of the catalyst particles addresses a major challenge in scaling up CO₂RR technology for practical use. Previously, the broad distribution of the different reaction products made it difficult to produce specific industrially relevant chemicals and fuels efficiently. This research offers a method to precisely control the distribution of CO₂RR products by manipulating the catalyst’s state. Furthermore, the developed process allows researchers to understand which structural features of the catalyst are responsible for a production of specific reaction products.

How the Process Works

The technique involves alternating electrical pulses. An applied negative (cathodic) potential is needed to drive CO₂ conversion, but it also induces the formation of copper nanoparticles. A subsequent pulse of more positive (anodic) potential, in turn, reverses this process, breaking the nanoparticles back into single atoms. By varying the duration of these pulses, the researchers can steer the sizes of formed nanoparticles, and control whether the catalyst exists mostly as single atoms, ultrasmall metal clusters, or larger metallic copper nanoparticles. Each form of the catalyst is better suited to producing different CO₂RR products. For instance, single copper atoms are efficient for hydrogen production, small clusters favor methane, and larger nanoparticles are best for ethylene production.

To monitor and adjust the catalyst’s transformation in real-time, the team used operando quick X-ray absorption spectroscopy. This advanced synchrotron-based technique allows scientists to observe the catalyst as it changes during the reaction with sub-second time resolution, ensuring the optimal conditions for the desired CO₂RR products.

Implications for Future Scientific Inquiry

This study not only provides a deeper understanding of catalyst behavior and the drastic structural transformations that can take place during operation It sheds light on the CO2 reduction reaction (CO2RR), showing how controlling the catalyst’s structure can impact the process. While the research highlights potential pathways for technological applications in greenhouse gas reduction and the production of green chemicals and fuels, it is primarily a significant stride in scientific inquiry, setting the stage for future advancements in the field.