Effects of activation temperature on densities and volumetric CO2 adsorption performance of alkali-activated carbons

Abstract Activated carbons (ACs) prepared by chemical activation were promising materials for CO 2 capture, but how to adjust their densities and volumetric CO 2 adsorption performance is unclear. We prepared ACs from petroleum coke by KOH activation to study impacts of activation temperature (540–820 °C) on densities and volumetric CO 2 adsorption performance of ACs. As the activation temperature increased, the true density rose whereas the apparent density and tap density decreased. The true density of ACs was dominated by aromatic-carbon ratio, not by the previously-believed graphitization degree. The activation temperature required to achieve the maximum volumetric low-pressure CO 2 uptake was lower than that needed to attain the highest gravimetric value (540 °C  2 adsorption capacity, its tap density and gravimetric CO 2 uptake should be moderate at least. The volumetric CO 2 /N 2 selectivity decreased with increasing activation temperature, mainly because of widening of micropore size distribution. This study provided new insights into ACs' densities, and highlighted judging ACs for CO2 capture by the previously-overlooked volumetric adsorption performance rather than only by the commonly-used gravimetric performance.