Coumarin 153 Dynamics in Ethylammonium Nitrate: The Effects of Dilution with Methanol

Sustainable Chemistry Pub Date : 2021-12-20 DOI:10.3390/suschem2040041

M. Heitz, Tyler J. Sabo, S. Robillard

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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.

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香豆素153在硝酸乙胺中的动力学:甲醇稀释的影响

用中性偶极溶质香豆素153 (C153)在295 K下对硝酸乙胺([N2,0,0,0+][NO3−]，EAN) +甲醇(MeOH)组成的二元溶剂体系在EAN摩尔分数(xIL = 0 - 1)范围内的魔力角强度衰减和动态荧光各向异性进行了测量。采用Stokes-Einstein-Debye (SED)流体力学理论作为模型框架，对C153旋转重定向动力学进行了评价。与使用阳离子或阴离子染料的文献报道相反，观察到与棒状SED预测的偏差，并表明结构域纳米非均质性对探针动力学有显著影响。稳态光谱显示，随着摩尔分数的变化，光谱峰和宽度的变化很小，但在xIL = 0.3时，吸收宽度下降了~170 cm−1，这表明C153感知到了溶液非均质性的变化。魔角强度衰减证实了稳态观测结果，激发态寿命在xIL = 0.2-0.4时发生了显著变化，EAN-EAN相互作用变得更加显著。C153平均旋转时间(⟨τrot⟩)与EAN增加显示显着的溶剂解耦。旋转数据拟合为幂律依赖，⟨τrot⟩∝(ηT)p，其中p = 0.82，表明EAN/MeOH溶液中存在动态异质性。随着EAN的增加，旋转次数显示出非均质性越来越显著，因为旋转次数系统地减少，远离水动力粘滞极限。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Sustainable Chemistry

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