Viscosities of iodobenzene + n-alkane mixtures at (288.15-308.15) K. Measurements and results from models

arXiv - PHYS - Chemical Physics Pub Date : 2024-09-09 DOI:arxiv-2409.05426

Luis Felipe Sanz, Juan Antonio González, Fernando Hevia, Daniel Lozano-Martín, Isaías García de la Fuente, José Carlos Cobos

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Abstract

Kinematic viscosities were measured for iodobenzene + n-alkane mixtures at (288.15-308.15) K and atmospheric pressure. Using our previous density data, dynamic viscosities ($\eta$), deviations in absolute viscosity ($\Delta \eta$) and quantities of viscous flow were determined. The McAllister, Grunberg-Nissan and Fang-He correlation equations and Bloomfield-Dewan's model (with residual Gibbs energies calculated using DISQUAC with interaction parameters available in the literature) were applied to iodobenzene, or 1-chloronaphthalene, or 1,2,4-trichlorobenzene, or methyl benzoate or benzene or cyclohexane + n-alkane systems. The dependence of $U_{\text{m,}V}^{\text{E}}$ (isochoric molar excess internal energy) and $\Delta \eta$ with $n$ (the number of C atoms of the n-alkane) shows that the fluidization loss of mixtures containing iodobenzene, 1,2,4-trichlorobenzene, or 1-chloronaphthalene when $n$ increases is due to a decrease upon mixing of the number of broken interactions between like molecules. The breaking of correlations of molecular orientations characteristic of longer n-alkanes may explain the decreased negative $\Delta \eta$ values of benzene mixtures with $n$ =14,16. The replacement, in this type of systems of benzene by cyclohexane leads to increased positive $\Delta \eta$ values, probably due to the different shape of cyclohexane. On the other hand, binary mixtures formed by one of the aromatic polar compounds mentioned above and a short n-alkane show large structural effects and large negative $\Delta \eta$ values. From the application of the models, it seems that dispersive interactions are dominant and that size effects are not relevant on $\eta$ values. The free volume model provides good results for most of the systems considered. Results improve when, within Bloomfield-Dewan's theory, the contribution to $\eta$ of the absolute reaction rate model is also considered.

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开氏 (288.15-308.15) 温度下碘苯 + 正构烷烃混合物的粘度。

在（288.15-308.15）K 和大气压力下测量了碘苯 + 正烷烃混合物的运动粘度。利用我们以前的密度数据，确定了动态粘度（$\eeta$）、绝对粘度偏差（$\delta \eeta$）和粘流量。McAllister、Grunberg-Nissan 和 Fang-He 相关方程以及 Bloomfield-Dewan 模型（使用 DISQUAC 和文献中提供的相互作用参数计算残余吉布斯能）被应用于碘苯、1-氯萘、1,2,4-三氯苯、苯甲酸甲酯或苯或环己烷 + 正烷烃系统。$U_{\text{m,}V}^{\text{E}}$（等时摩尔过剩内能）和 $\Delta \eta$ 与 $n$ （当时烷烃的 C 原子数）的关系表明，当 $n$ 增加时，含有碘苯、1,2,4-三氯苯或 1-氯萘的混合物的流化损失是由于同类分子之间的断裂相互作用的数量在混合时增加了。较长正构烷烃所特有的分子取向相关性的破坏可以解释为什么在 $n$ =14,16 时苯混合物的负 $\Delta\eta$ 值会降低。在这类体系中，用环己烷代替苯会导致正 $\Delta\eta$ 值增加，这可能是由于环己烷的形状不同。另一方面，由上述一种芳香族极性化合物和一种短的正烷烃形成的二元混合物显示出较大的结构效应和较大的负 $\Delta\eta$ 值。从模型的应用来看，分散相互作用似乎占主导地位，尺寸效应与 $\eta$ 值无关。自由体积模型为所考虑的大多数系统提供了良好的结果。在布卢姆菲尔德-迪万理论中，如果同时考虑绝对反应速率模型对 $\eta$ 的贡献，结果会有所改善。

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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arXiv - PHYS - Chemical Physics

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