Integrated Electrochemical CO₂ Capture and Conversion for Value-Added C₂+ Products
We evaluate the role of catalysts, electrolyzer design, and membrane materials to improve the performance of CO₂ electrolysis. Our fundamental research includes studying the thermodynamics and kinetics of CO₂ reduction, alongside investigating reaction intermediates using both experimental and computational approaches.
We will systematically evaluate the performance of H-cells, flow reactors, and membrane electrode assemblies to investigate reaction mechanisms, followed by an assessment of scalability and long-term stability. This approach will facilitate the design of efficient, scalable, and sustainable electrochemical CO₂ conversion systems.
We will systematically evaluate the performance of H-cells, flow reactors, and membrane electrode assemblies to investigate reaction mechanisms, followed by an assessment of scalability and long-term stability. This approach will facilitate the design of efficient, scalable, and sustainable electrochemical CO₂ conversion systems.
We focus on the electrochemical reduction of CO₂ into high-value C₂+ products, integrating this process with direct CO₂ capture from ambient air through the design of specialized electrolyzers and compounds. This strategy enables the direct conversion of atmospheric CO₂ into valuable chemical feedstocks, supporting decarbonization efforts across industrial sectors.
Stay tuned as we will be sharing our findings and progress on this exciting journey. :)