Helmholtz energy models for dipole interactions: Review and comprehensive assessment

IF 2.8 3区工程技术 Q3 CHEMISTRY, PHYSICAL Fluid Phase Equilibria Pub Date : 2024-07-01 DOI:10.1016/j.fluid.2024.114168

Jens Staubach, Hans Hasse, Simon Stephan

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Abstract

Dipolar interactions play an important role for thermodynamic properties of many fluids and accordingly for their modeling. In molecular-based equation of state models, the effect of dipolar interactions is usually described by Helmholtz energy models. There are several Helmholtz energy models for dipolar interactions available in the literature today. In this work, eight dipole contribution models describing the dipole–dipole interactions of fluids were critically assessed by comparing their results with molecular simulation reference data of Stockmayer fluids. Therefore, the dipole contribution models were combined with an accurate Lennard-Jones (LJ) Helmholtz energy model. The following thermodynamic properties were considered in the comparison: vapor pressure, saturated densities, enthalpy of vaporization, surface tension (by using density gradient theory), critical point, second virial coefficient, and thermodynamic properties at homogeneous state points, such as the Helmholtz energy, pressure, chemical potential, internal energy, isochoric heat capacity, isobaric heat capacity, thermal expansion coefficient, isothermal compressibility, thermal pressure coefficient, speed of sound, Joule–Thomson coefficient, and Grüneisen parameter. For the evaluation of the dipole contribution models, molecular simulations for the Stockmayer fluid with the dipole moments of $μ^{2} / 4 π ϵ_{0} ɛ σ^{3} = 0.5, 1, 2, 3, 4, 5$ were carried out. The results indicate, that all considered dipole models exhibit some significant weaknesses. Nevertheless, some dipole contribution models are found to provide a robust description for many properties and state ranges. Overall, the deviations of the dipole contribution models from the Stockmayer simulation data are, in most cases, an order of magnitude higher than the deviations of the LJ EOS from LJ simulation data.

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偶极相互作用的赫尔姆霍兹能量模型：回顾与全面评估

偶极相互作用对许多流体的热力学性质和建模起着重要作用。在基于分子的状态方程模型中，偶极相互作用的影响通常由亥姆霍兹能量模型来描述。目前，文献中有多种偶极相互作用的亥姆霍兹能量模型。在这项工作中，通过将描述流体偶极-偶极相互作用的八个偶极贡献模型的结果与斯托克迈尔流体的分子模拟参考数据进行比较，对它们进行了严格的评估。因此，偶极子贡献模型与精确的伦纳德-琼斯（LJ）亥姆霍兹能量模型相结合。比较中考虑了以下热力学性质：蒸气压、饱和密度、汽化焓、表面张力（利用密度梯度理论）、临界点、第二维里系数，以及均相态点的热力学性质，如亥姆霍兹能、压力、化学势、内能、等时热容量、等压热容量、热膨胀系数、等温可压缩性、热压系数、声速、焦耳-汤姆森系数和格鲁尼森参数。为了评估偶极贡献模型，对偶极矩为 μ2/4πϵ0ɛσ3=0.5,1,2,3,4,5的斯托克迈尔流体进行了分子模拟。结果表明，所有考虑的偶极子模型都存在一些明显的缺陷。不过，一些偶极贡献模型对许多性质和状态范围提供了稳健的描述。总体而言，偶极贡献模型与斯托克迈耶模拟数据的偏差在大多数情况下比 LJ EOS 与 LJ 模拟数据的偏差高出一个数量级。

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来源期刊

Fluid Phase Equilibria 工程技术-工程：化工

CiteScore

5.30

自引率

15.40%

发文量

223

审稿时长

53 days

期刊介绍： Fluid Phase Equilibria publishes high-quality papers dealing with experimental, theoretical, and applied research related to equilibrium and transport properties of fluids, solids, and interfaces. Subjects of interest include physical/phase and chemical equilibria; equilibrium and nonequilibrium thermophysical properties; fundamental thermodynamic relations; and stability. The systems central to the journal include pure substances and mixtures of organic and inorganic materials, including polymers, biochemicals, and surfactants with sufficient characterization of composition and purity for the results to be reproduced. Alloys are of interest only when thermodynamic studies are included, purely material studies will not be considered. In all cases, authors are expected to provide physical or chemical interpretations of the results. Experimental research can include measurements under all conditions of temperature, pressure, and composition, including critical and supercritical. Measurements are to be associated with systems and conditions of fundamental or applied interest, and may not be only a collection of routine data, such as physical property or solubility measurements at limited pressures and temperatures close to ambient, or surfactant studies focussed strictly on micellisation or micelle structure. Papers reporting common data must be accompanied by new physical insights and/or contemporary or new theory or techniques.