Dynamic viscosity, interfacial tension and diffusion coefficient of n-hexane, cyclohexane, 2-methylpentane with dissolved CO2

IF 2.2 3区工程技术 Q3 CHEMISTRY, PHYSICAL

Journal of Chemical Thermodynamics Pub Date : 2024-08-05 DOI:10.1016/j.jct.2024.107360

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引用次数: 0

Abstract

In this work, n-hexane, cyclohexane and 2-methylpentane were selected to represent linear-alkane, cycloalkane and branched-alkane, respectively. Based on the dynamic light method (DLS), the viscosity, interfacial tension and diffusion coefficient of n-hexane/CO₂, cyclohexane/CO₂ and 2-methylpentane/CO₂ systems under saturation condition were measured in order to explore the change trend of thermophysical properties of the systems with the same carbon atom number but different molecular structures. The experiments were conducted at the temperatures of 303, 343 and 383 K and at pressures up to 5.64 MPa. The expanded uncertainties（k = 2）of dynamic viscosity, interfacial tension and diffusion coefficient were 3 %, 3 % and 4.4 % respectively. The experimental results show that n-hexane and 2-methylpentane with similar molecular structure have more similar value of the properties. The effects of different alkane structures on system viscosity, interfacial tension, and diffusion coefficient were explained at the molecular level through radial distribution function, interface thickness, and CO₂ coordination number. At 303.15 K and 4 MPa, the peak radial distribution function of CO₂/cyclohexane is 1.845, which is greater than that of CO₂/n-hexane and CO₂/2-methylpentane molecules. It has been proven that the arrangement of CO₂/cyclohexane is more orderly, resulting in higher viscosity and lower diffusion coefficient of the system. The interface thickness of CO₂/cyclohexane is 6.13 nm, which is smaller than CO₂/n-hexane (7.53 nm) and CO₂/2-methylpentane (6.3 nm). The smaller the interface thickness, the more compact the structure, the stronger the intermolecular forces, and the greater the interfacial tension. At 303.15 K and 2 MPa, the number of CO₂ coordination sites within 1 nm around liquid phase alkanes is 3.96, which is smaller than 4.78 for cyclohexane and 6.62 for 2-methylpentane. Prove that the coordination number is directly proportional to the diffusion coefficient and inversely proportional to viscosity and interfacial tension.

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正己烷、环己烷、2-甲基戊烷与溶解二氧化碳的动态粘度、界面张力和扩散系数

本研究选择正己烷、环己烷和 2-甲基戊烷分别代表直链烷烃、环烷烃和支链烷烃。基于动态光法（DLS），测量了正己烷/CO2、环己烷/CO2 和 2-甲基戊烷/CO2 体系在饱和状态下的粘度、界面张力和扩散系数，以探讨碳原子数相同但分子结构不同的体系的热物理性质的变化趋势。实验在 303、343 和 383 K 的温度和最高 5.64 MPa 的压力下进行。动态粘度、界面张力和扩散系数的扩展不确定度（k = 2）分别为 3%、3% 和 4.4%。实验结果表明，分子结构相似的正己烷和 2-甲基戊烷具有更相似的特性值。不同烷烃结构对系统粘度、界面张力和扩散系数的影响是通过径向分布函数、界面厚度和 CO2 配位数在分子水平上解释的。在 303.15 K 和 4 MPa 条件下，CO2/环己烷的径向分布函数峰值为 1.845，大于 CO2/正己烷和 CO2/2 甲基戊烷分子的径向分布函数峰值。实验证明，CO2/环己烷的排列更有序，因此体系的粘度更高，扩散系数更低。CO2/ 环己烷的界面厚度为 6.13 nm，小于 CO2/ 正己烷（7.53 nm）和 CO2/2-甲基戊烷（6.3 nm）。界面厚度越小，结构越紧凑，分子间作用力越强，界面张力越大。在 303.15 K 和 2 MPa 条件下，液相烷烃周围 1 nm 范围内的 CO2 配位点数为 3.96，小于环己烷的 4.78 和 2-甲基戊烷的 6.62。证明配位数与扩散系数成正比，与粘度和界面张力成反比。

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来源期刊

Journal of Chemical Thermodynamics 工程技术-热力学

CiteScore

5.60

自引率

15.40%

发文量

199

审稿时长

79 days

期刊介绍： The Journal of Chemical Thermodynamics exists primarily for dissemination of significant new knowledge in experimental equilibrium thermodynamics and transport properties of chemical systems. The defining attributes of The Journal are the quality and relevance of the papers published. The Journal publishes work relating to gases, liquids, solids, polymers, mixtures, solutions and interfaces. Studies on systems with variability, such as biological or bio-based materials, gas hydrates, among others, will also be considered provided these are well characterized and reproducible where possible. Experimental methods should be described in sufficient detail to allow critical assessment of the accuracy claimed. Authors are encouraged to provide physical or chemical interpretations of the results. Articles can contain modelling sections providing representations of data or molecular insights into the properties or transformations studied. Theoretical papers on chemical thermodynamics using molecular theory or modelling are also considered. The Journal welcomes review articles in the field of chemical thermodynamics but prospective authors should first consult one of the Editors concerning the suitability of the proposed review. Contributions of a routine nature or reporting on uncharacterised materials are not accepted.