Although the use of non-carbon energy technologies is increasing, we are still far from matching the pace of the growing population’s energy demand. Global energy-related CO2 emissions rose by 6% in 2021, reaching a historic high of 36.3 gigatones (Gt). Flue gas streams are among the most polluting gas mixtures, essentially comprising CO2 (15%), N2 (75%) and water. Adsorption is key for separating CO2 from mixtures, such as flue gas (CO2/N2, CO2/H2) or biogas (CO2/CH4). Even when strengthening pre-2030 mitigation action is combined with very stringent long-term policies, cumulative CO2 emissions from fossil fuel will remain at 850-1150 Gt during 2016-2100. Thus, 640-950 GtCO2 removal is required for limiting end-of-century warming to 1.5 ºC.
CO2 capture from large point sources, which account for ~50% of released CO2, is identified as a major solution to mitigate CO2 emissions. Post-combustion capture using aqueous solutions has been used commercially, however costs are high and there are corrosion and health/environment risks. To overcome such limitations, solid adsorbents have been widely investigated showing reduced regeneration energy, greater CO2 capacity and selectivity with the ability to operate over a wider range of temperatures. A plethora of solid adsorbents has emerged including activated carbons, ion-exchange resins, zeolites, porous silicates, metal oxides, organic-inorganic hybrid sorbents and composite materials.
NMR4CO2 encompasses the design of novel solid-state NMR methods to study the CO2 adsorption process in amine-modified porous silicas, comprising in-situ flow NMR, dynamic nuclear polarization NMR, and isotopically labelled gas mixtures. Important outcomes include: i) identification of competing CO2 chemisorption pathways; ii) effect on CO2 speciation of textural properties, amine type, inter-amine spacing, and amine-amine/amine-support cooperative effects; iii) real-time monitoring of acid gas speciation in multiple adsorption/desorption cycles; iv) identification of sorbent deactivation species; v) effect of pressure on CO2 speciation and vi) improvement of sorbent properties by synthetic modification.