Static Dielectric Constants, Densities, Refractive Indices and Related Properties of Binary Mixtures at Various Temperatures Under Atmospheric Pressure

IF 0.9 Q4 THERMODYNAMICS International Journal of Thermodynamics Pub Date : 2022-08-25 DOI:10.5541/ijot.1017174

Vaijanath Navarkhele, A. Navarkhele

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Abstract

Experimental dielectric constants at (293.15, 298.15, 303.15) K, densities and refractive indices at 293.15 K are reported for water- ethanol and water- n-butanol binary mixture systems over the entire volume fraction range and atmospheric pressure. From the experimental dielectric data, the excess dielectric constant, effective Kirkwood correlation factor, Bruggeman factor and from density and refractive index data various parameters and their excess properties like excess density, excess refractive index, excess molar polarization, and excess molar volume were estimated and reported in the study. The static dielectric constant of the studied binary mixtures decreases with increase in temperature and volume fraction of the solutes. The density values are decreasing and refractive indices are increasing with increasing volume fraction of ethanol and n-butanol in water. Excess molar volumes values of ethanol and n-butanol are negative over the entire volume fraction range shows the presence of intermolecular interaction and hydrogen bonding in both the binary mixtures.

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大气压下不同温度下二元混合物的静态介电常数、密度、折射率及相关性质

报道了在整个体积分数范围和大气压下，水-乙醇和水-正丁醇二元混合物体系在（293.15298.15303.15）K下的实验介电常数、293.15K下的密度和折射率。根据实验介电数据、过量介电常数、有效柯克伍德相关因子、布鲁格曼因子以及密度和折射率数据，估计并报告了各种参数及其过量性质，如过量密度、过量折射率、过量摩尔极化和过量摩尔体积。所研究的二元混合物的静态介电常数随着温度和溶质体积分数的增加而降低。随着乙醇和正丁醇在水中的体积分数的增加，密度值降低，折射率增加。乙醇和正丁醇的过量摩尔体积值在整个体积分数范围内为负，表明在两种二元混合物中都存在分子间相互作用和氢键。

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来源期刊

International Journal of Thermodynamics THERMODYNAMICS-

CiteScore

1.50

自引率

12.50%

发文量

期刊介绍： The purpose and scope of the International Journal of Thermodynamics is · to provide a forum for the publication of original theoretical and applied work in the field of thermodynamics as it relates to systems, states, processes, and both non-equilibrium and equilibrium phenomena at all temporal and spatial scales. · to provide a multidisciplinary and international platform for the dissemination to academia and industry of both scientific and engineering contributions, which touch upon a broad class of disciplines that are foundationally linked to thermodynamics and the methods and analyses derived there from. · to assess how both the first and particularly the second laws of thermodynamics touch upon these disciplines. · to highlight innovative & pioneer research in the field of thermodynamics in the following subjects (but not limited to the following, novel research in new areas are strongly suggested): o Entropy in thermodynamics and information theory. o Thermodynamics in process intensification. o Biothermodynamics (topics such as self-organization far from equilibrium etc.) o Thermodynamics of nonadditive systems. o Nonequilibrium thermal complex systems. o Sustainable design and thermodynamics. o Engineering thermodynamics. o Energy.