AI Article Synopsis
- The study examined time-resolved fluorescence and anisotropy decay of 2-aminoquinoline (2AQ) in various ionic liquids, focusing on both aromatic and nonaromatic types.
- Results revealed the formation of pi-pi aromatic complexes in aromatic ionic liquids, which was not observed in nonaromatic counterparts, indicating different interactions.
- Rotational diffusion of 2AQ was slower in aromatic ionic liquids due to solute-solvent complex formation, and adding acetonitrile disrupted these structures, highlighting the importance of aromaticity in the local structure of imidazolium-based ionic liquids.
Article Abstract
Time-resolved fluorescence spectra and fluorescence anisotropy decay of 2-aminoquinoline (2AQ) have been measured in eight room-temperature ionic liquids, including five imidazolium-based aromatic ionic liquids and three nonaromatic ionic liquids. The same experiments have also been carried out in several ordinary molecular liquids for comparison. The observed time-resolved fluorescence spectra indicate the formation of pi-pi aromatic complexes of 2AQ in some of the aromatic ionic liquids but not in the nonaromatic ionic liquids. The fluorescence anisotropy decay data show unusually slow rotational diffusion of 2AQ in the aromatic ionic liquids, suggesting the formation of solute-solvent complexes. The probe 2AQ molecule is likely to be incorporated in the possible local structure of ionic liquids, and hence the anisotropy decays only through the rotation of the whole local structure, making the apparent rotational diffusion of 2AQ slow. The rotational diffusion time decreases rapidly by adding a small amount of acetonitrile to the solution. This observation is interpreted in terms of the local structure formation in the aromatic ionic liquids and its destruction by acetonitrile. No unusual behavior upon addition of acetonitrile has been found for the nonaromatic ionic liquids. It is argued that the aromaticity of the imidazolium cation plays a key role in the local structure formation in imidazolium-based ionic liquids.
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