Subventions et des contributions :

Subvention ou bourse octroyée s'appliquant à plus d'un exercice financier. (2017-2018 à 2022-2023)

The electrocatalytic reduction of CO 2 is a reaction that has captured the interest of generations of scientists and currently commands significant attention in industrial, government and academic circles. Much of the modern interest in electrochemical reduction of CO 2 originates from the fact that, when coupled with water oxidation, this reaction provides a viable means to generate a sustainable, global carbon cycle. Such a cycle would act to mitigate the impact of anthropogenic CO 2 emissions while providing a non-fossil fuel feedstock for synthesizing useful chemicals, ranging from hydrocarbon fuels to commodity chemicals. Despite decades of research, however, 2-electron reduction products with limited commercial/industrial interest remain the only products that can be reliably synthesized with acceptable selectivity. The proposed research program seeks to establish a long-term, strategic focus that will utilize state-of-the-art spectroelectrochemical techniques to perform mechanistic studies to enable the rational design of catalysts capable of selective conversion of CO 2 into high value, commercially relevant chemicals.

Numerous reports have described changes to the electrochemical reaction system that enable conversion of CO 2 into mixtures of desirable hydrocarbon products. Strategies that have enabled hydrocarbon synthesis include electrode composition turning, electrode surface engineering, and addition of co-catalysts to the electrolyte solution. These approaches tend to produce a diverse mixture of chemical products, however, and the ability to selectively synthesize desirable products remains elusive. This research program will capitalize on recent advances in spectroscopic instrumentation and techniques to acquire structural information on heterogeneous electrocatalyst surfaces under operational conditions (i.e. in-situ spectroelectrochemistry). Spectroelectrochemical measurements performed during operation will enable changes in chemistry at/near the electrode surface to be monitored, yielding information regarding reaction mechanisms. Repetition of the experiments upon strategic, systematic variation of components in the overall system, upon addition of a series of co-catalysts for example, will reveal the impact of the reaction component on the reaction mechanism. The library of data that will be generated throughout this research program will be comparatively analyzed to reveal design principles enabling the rational design of electrocatalysts and reaction system modifications to improve the selectivity of electrocatalytic CO 2 reduction.