"Integrated Capture and Conversion of Dilute CO2 Using an Oxygen Tolerant Porous Carbon Modified Gas Diffusion Electrode" ACS Energy Letters
Flue gas is exhausted from home furnaces, fireplaces and even industrial plants, and it carries polluting carbon dioxide (CO2) into the atmosphere. To help mitigate these emissions, researchers reporting in ACS Energy Letters have designed a specialized electrode that captures airborne CO2 and directly converts it into a useful chemical material called formic acid. The system performed better than existing electrodes in tests with simulated flue gas and at ambient CO2 concentrations.
"This work shows that carbon capture and conversion do not need to be treated as separate steps. By integrating both functions into a single electrode, we demonstrate a simpler pathway for CO2 utilization under realistic gas conditions," explains Wonyong Choi, a corresponding author on the study.
Capturing CO2 from the air should be relatively simple - after all, plants do it all the time. But converting the gas into something useful is difficult, and it is a crucial step in ensuring that carbon capture methods are widely implemented. In industrial emissions like flue gas, CO2 is often diluted amid other gases such as nitrogen and oxygen. However, existing conversion methods require highly concentrated CO2 that's already separated from other gases to function efficiently. So, Donglai Pan, Myoung Hwan Oh, Wonyong Choi and colleagues wanted to design a carbon capture and conversion system that functioned in conditions consistent with real-world flue gas and could convert even small amounts of captured CO2 into a useful product.
The team constructed an electrode that allows gas to diffuse in, then catches and converts the airborne CO2. The electrode consists of three layers: a specialized carbon-capturing material, gas-permeable carbon paper, and catalytic tin(IV) oxide. This design converted CO2 gas directly into formic acid, a valuable starting material for a variety of chemical applications, including fuel cells.
In tests with pure CO2 gas, the new electrode was around 40% more efficient than other existing carbon-converting electrodes under comparable laboratory conditions. More importantly, in tests with a simulated flue gas containing 15% CO2, 8% oxygen gas and 77% nitrogen gas, it continued to produce a substantial amount of formic acid, with the other systems producing a negligible amount. Finally, the new electrode system captured CO2 at concentrations similar to current atmospheric levels, demonstrating its utility to operate in ambient air conditions. The researchers say that this work offers a promising strategy for integrating CO2 capture into practical industrial applications, and they hope that it can lead to similar systems to capture other greenhouse gases like methane.
The authors acknowledge funding from the National Research Foundation of Korea.
