Post-combustion carbon dioxide adsorption of concurrent activated and surface modified palm kernel shell-derived activated carbon

This research applied a concurrent activation and surface modification (CAM) process to synthesize palm kernel shell-derived activated carbon (PKSdAC) to obtain CO2 affinity surface functionalization. The CAM process is a simplified activated carbon activation process that is cost-effective. The CAM process used in this study integrates sulphuric acid activation and barium chloride functionalization. The formation of barium sulphate is targeted to incorporate barium through a reduction process with carbon-containing material at elevated temperatures into PKSdAC to obtain basic metal surfaces functional group for chemical adsorption. The optimal temperature for CAM-PKSdAC CO2 adsorption performance was at 40-60 degrees C, established through temperature-programmed desorption of CO2 (TPD-CO2) analysis. The CAM-PKSdAC adsorption performance was tested using a lab-scale adsorption system. The bed CO2 content was determined using gas chromatography coupled with a thermal conductivity detector (GC-TCD) by manual syringe injection. CAM-PKSdAC exhibited a high CO2 adsorption capacity of 0.89 mmol g(-1) from TPD-CO2, and 1.91 mmol g(-1) from GC-TCD at 40 degrees C and 1 bar. It showed comparable CO2 adsorption capacity to conventional surface modified-activated PKSdAC (1.96 mmol g(-1)) while higher than commercial and modified ACs (1.14-1.60 mmol g(-1)), but lower than potassium hydroxide modified ACs (1.81-2.10 mmol g(-1)) at 40 degrees C and 1 bar. Barium promoted chemisorption of CO2 as supplementary reaction, which increases adsorption capacity. The non-linear Dubinin Radushkevich model strongly correlates with the experimental adsorption data for CAM-PKSdAC adsorption, indicating the physisorption process via micropore filling on CAM-PKSdAC. CAM-PKSdAC showed moderate reusability with negligible variation in adsorption capacity after 10 adsorption-desorption cycles. (c) 2024 Society of Chemical Industry and John Wiley & Sons, Ltd.