Abstract
The effect of CO2 absorption on the aromaticity and hydrogen bonding in ionic liquids is investigated. Five different ionic liquids with choline based cations and aprotic N-heterocyclic anions were synthesized. Purity and structures of the synthesized ionic liquids were characterized by 1H and 13C NMR spectroscopy. CO2 capture performance was studied at 20 °C and 40 °C under three different pressures (1, 3, 6 bar). The IL [N1,1,6,2OH][4-Triz] showed the highest CO2 capture capacity (28.6 wt%, 1.57 mol of CO2 per mol of the IL, 6.48 mol of CO2 per kg of the ionic liquid) at 20 °C and 1 bar. The high CO2 capture capacity of the [N1,1,6,2OH][4-Triz] IL is due to the formation of carbonic acid (-OCO2H) together with carbamate by participation of the -OH group of the [N1,1,6,2OH]+ cation in the CO2 capture process. The structure of the adduct formed by CO2 reaction with the IL [N1,1,6,2OH][4-Triz] was probed by using IR, 13C NMR and 1H-13C HMBC NMR experiments utilizing 13C labeled CO2 gas. 1H and 13C PFG NMR studies were performed before and after CO2 absorption to explore the effect of cation-anion structures on the microscopic ion dynamics in ILs. The ionic mobility was significantly increased after CO2 reaction due to lowering of aromaticity in the case of ILs with aromatic N-heterocyclic anions.
Highlights
Diffusivity of molecules, ions and their aggregates is a property of any liquid as a result of thermal motion.[6]
A choline based cation [N1,1,6,2OH]+ and a choline based ether functionalized cation [N1,1,6,2O4]+ are selected to investigate the effect of hydrogen bonding and ether functionalization on the ionic mobility before and after CO2 absorption
Viscosity of the four different ionic liquids [N1,1,6,2OH][Im], [N1,1,6,2OH][4-Triz], [N1,1,6,2OH][Succ] and [N1,1,6,2O4][4-Triz], which were liquid at room temperature, was measured as a function of temperature (ESI,† S10)
Summary
Diffusivity ( known as self-diffusion) of molecules, ions and their aggregates is a property of any liquid as a result of thermal motion.[6]. Nuclear magnetic resonance (NMR) spectroscopy is an appropriate technique for the investigation of the diffusion of ions and sorbent additives in the ILs.[14]
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