@ARTICLE{10.3389/fenrg.2017.00013, AUTHOR={Reed, Daniel G. and Dowson, George R. M. and Styring, Peter}, TITLE={Cellulose-Supported Ionic Liquids for Low-Cost Pressure Swing CO2 Capture}, JOURNAL={Frontiers in Energy Research}, VOLUME={5}, YEAR={2017}, URL={https://www.frontiersin.org/articles/10.3389/fenrg.2017.00013}, DOI={10.3389/fenrg.2017.00013}, ISSN={2296-598X}, ABSTRACT={Reducing the cost of capturing CO2 from point source emitters is a major challenge facing carbon capture, utilization, and storage. While solid ionic liquids (SoILs) have been shown to allow selective and rapid CO2 capture by pressure swing separation of flue gases, expectations of their high cost hinders their potential application. Cellulose is found to be a reliable, cheap, and sustainable support for a range of SoILs, reducing the total sorbent cost by improving the efficiency of the ionic liquid (IL) through increased ionic surface area that results from coating. It was also found that cellulose support imparts surface characteristics, which increased total sorbent uptake. Combined, these effects allowed a fourfold to eightfold improvement in uptake per gram of IL for SoILs that have previously shown high uptake and a 9- to 39-fold improvement for those with previously poor uptake. This offers the potential to drastically reduce the amount of IL required to separate a given gas volume. Furthermore, the fast kinetics are retained, with adsorb–desorb cycles taking place over a matter of seconds. This means that rapid cycling can be achieved, which results in high cumulative separation capacity relative to a conventional temperature swing process. The supported materials show an optimum at 75% cellulose:25% IL as a result of even coating of the cellulose surface. The projected reduction in plant size and operational costs represents a potentially ground-breaking step forward in carbon dioxide capture technologies.} }