Abstract
Magic angle intensity decay and dynamic fluorescence anisotropy measurements were made on the binary solvent system composed of ethylammonium nitrate ([N2,0,0,0+][NO3−], EAN) + methanol (MeOH) across the complete EAN mole fraction range (xIL = 0–1) using the neutral dipolar solute coumarin 153 (C153) at 295 K. Stokes–Einstein–Debye (SED) hydrodynamic theory was used as a model framework to assess the C153 rotational reorientation dynamics. Departure from stick SED prediction was observed (in contrast to literature reports that used cationic or anionic dyes) and indicated a significant influence of domain nanoheterogeneity on probe dynamics. Steady-state spectroscopy indicated minimal changes in spectral peak and width with mole fraction, except at xIL = 0.3 where absorption widths decreased by ~170 cm−1, signaling that C153 sensed a change in solution heterogeneity. Magic angle intensity decays corroborated the steady-state observation and the excited-state lifetimes showed a marked change from xIL = 0.2–0.4 where EAN-EAN interactions became notably more significant. C153 average rotation times (⟨τrot⟩) showed significant solvent decoupling with increased EAN. The rotational data were fit to a power law dependence, ⟨τrot⟩ ∝ (ηT)p, where p = 0.82, demonstrating the presence of dynamic heterogeneity in the EAN/MeOH solutions. With increased EAN, rotation times showed that the heterogeneity became increasingly more significant since the rotation times systematically decreased away from the hydrodynamic stick limit.
Highlights
We report the results of steady-state absorption and emission for coumarin 153 (C153) in neat ethylammonium nitrate (EAN) as a function of temperature
For EAN with only a C2 chain, aggregation is not a significant consideration, so what governs structural variation? Formation of hydrogen bonds between EAN, MeOH and C153 collectively would seem to account for the slowed hydrodynamic-like rotational dynamics as well as the formation of polar and apolar domains within the EAN structure, and these interactions have been discussed in detail elsewhere [18,31,36,65,66]
We have studied the EAN/MeOH binary solvent system over the entire range of IL mole fraction using the well-known, solvent sensitive, neutral fluorescent molecule
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. The canonical ionic liquid, ethylammonium nitrate (EAN, Scheme 1), was reportedly identified by Paul Walden more than a century ago. Room temperature ionic liquids have been intensively studied and become a very popular medium for synthetic chemistry and various applications [1,2,3,4,5]. Protic ionic liquids (PILs) are among the most studied and reviews have discussed structure-property relationships, physicochemical properties, electrochemical, chromatographic and synthetic applications [3,6]
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