Electrochemical CO₂ Direct Capture (e-DAC) from Air Using Redox-Active Compounds
Developing High-Performance Redox-Active Compounds for Efficient e-DAC
Our work spans from fundamental studies to the scaling-up of reactions, with the goal of creating a fully integrated system for CO₂ capture and conversion. By combining innovative materials with advanced electrochemical design, we aim to improve both energy efficiency and oxygen stability while addressing the limitations of conventional CO₂ capture methods. Through the integration of catalysts and electrochemical flow systems, we develop scalable solutions for CO₂ capture under ambient conditions with minimal energy input.
Fundamental Insights into the Reaction Mechanism for Enhanced e-DAC Performance
Despite these challenges, aqueous systems offer advantages such as lower operational costs and better scalability, making them a promising candidate for large-scale CO₂ capture. Our team is focused on understanding these fundamental mechanisms to optimize the efficiency and scalability of e-DAC systems, paving the way for more effective CO₂ capture solutions.