Microfluidic analysis of seawater-based CO2 capture in an amine solution with nickel nanoparticle catalysts

Post-combustion CO2 capture methods like amine scrubbing are currently being utilized to reduce CO2 emissions from fossil fuel power plants. Aqueous monoethanolamine (MEA) solutions are typically used in these processes due to their high CO2 absorption capacity and rapid reaction rate, but these solutions also produce environmentally harmful toxic wastewater and consume large amounts of freshwater. This research analyzes the effectiveness of seawater-based MEA solutions containing nickel nanoparticles (NiNPs) as catalysts, with the goal to minimize the amount of MEA required in the amine scrubbing process and eliminate the use of freshwater. This study is the first to use natural seawater solutions as an alternative to freshwater solutions for CO2 capture. In a microfluidic environment, CO2 microbubbles were generated and their change in size with respect to time was observed to determine the CO2 absorption capacity and rate of the test solutions. Pure seawater demonstrated comparable CO2 absorption to deionized (DI) water. Seawater-based amine solutions absorbed merely 1.79 % less CO2 than DI water-based amine solutions. Seawater-based amine solutions demonstrated faster CO2 absorption rates than their freshwater counterparts. Lastly, to further optimize CO2 absorption, NiNPs were added to each test solution. Seawater with MEA and NiNPs absorbed only 1.15 % less than its DI water counterpart, confirming seawater's potential as amine-based solvent for industrial CO2 capture applications.

Automated summary

This study evaluates the effectiveness of seawater-based MEA solutions with NiNPs as catalysts for CO2 capture, aiming to reduce MEA usage and eliminate the need for freshwater. In a microfluidic environment, seawater-based amine solutions showed comparable CO2 absorption to DI water, with faster absorption rates. Furthermore, the addition of NiNPs optimized CO2 absorption, confirming seawater as a potential solvent for industrial CO2 capture applications.