Direct air capture of CO2 by amine-impregnated resin: The effect of resin pore structure and humid conditions
Jiali Hua, Xuehua Shen, Xianfeng Jiao, Lin Han, Guanghuan Li, Xin Sun, Feng Yan, Hao Wu, Zuotai Zhang
Abstract
• The X5 resin had a large pore volume (1.90 cm 3 /g) and bimodal porous networks. • Polyethylenimine was impregnated into X5 for CO 2 capture from ambient air. • The 50 %PEI@X5 achieved a high CO 2 uptake of 118 mg/g at 400 ppm CO 2 and 25 °C. • The adsorbent exhibited superb cyclic stability with no decay observed. • Introducing 25 % H 2 O (relative humidity) significantly improved the CO 2 uptake. Direct air capture (DAC) by solid amine adsorbents is a promising technology to curb the increasing atmospheric CO 2 level. Despite extensive efforts, there are still limited improvements for this type of materials in their CO 2 uptake and adsorption kinetics under ultra-dilute conditions. And most current research focuses on powdered adsorbents, which need to be granulated or fabricated into devices for DAC application, resulting in a further decline in CO 2 uptake. Herein, a series of commercial resin particles (1.0 mm) were used as supports, and it was found that X5 exhibited favorable support characteristics in the preparation of solid amine adsorbents. Notably, X5 possessed a large pore volume of 1.90 cm 3 /g and featured a hierarchical bimodal porous network comprising mesopores and macropores. The prepared adsorbents (PEI@X5) had considerable polyethyleneimine (PEI) dispersion even at PEI content up to 50 %, and thus demonstrated excellent CO 2 adsorption performances with high CO 2 uptakes of 118 or 108 mg/g in TGA or fixed bed under simulated ambient air conditions (25 °C, 400 ppm CO 2 ). Additionally, the adsorbents exhibited superb cyclic stability with no decay observed over 10 adsorption-regeneration cycles. The introduction of 25 % relative humidity (RH) of water vapor significantly improved the CO 2 uptake of the adsorbent to 130 mg/g, with a lifting efficiency of 20.4 %. However, further increases in RH reduced the CO 2 uptake and adsorption rate due to the excessive adsorption water, which leached part of PEI from the pores of 50 %PEI@X5. Considering the commercial production of raw materials, the facile synthesis of 50 %PEI@X5, and its superior CO 2 capture efficiency, these findings open up new avenues for DAC technology.