Three Types of the Two-Phase Surface Tension of Molecules in Mesoporous Systems and Methods for Their Calculation

IF 0.8 Q3 Engineering

Nanotechnologies in Russia Pub Date : 2024-08-06 DOI:10.1134/S263516762460041X

Yu. K. Tovbin, E. S. Zaitseva

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Abstract

At temperatures T < T_c(H) (where T_c(H) is the critical temperature and H is the characteristic pore size), in all mesoporous systems sorbed adsorbate molecules are separated into two coexisting phases “vapor in a pore” and “liquid in a pore”. The conditions for such adsorbate separation depend on the pore width and adsorbent–adsorbate interaction energies. The distribution of an adsorbate over the pore volume in different materials plays an important role in the processes of substance transfer and the establishment of an equilibrium state in them. The separation of molecules is accompanied by the formation of menisci at the vapor–liquid interface. They largely determine the overall resistance to the process of mass transfer through porous materials. The most advanced results on the description of vapor–liquid interfaces are obtained on the basis of the so-called molecular lattice-gas model, which makes it possible to calculate the molecular distributions in heterogeneously distributed models of transition regions with equal accuracy. Nondeformable pore walls create an external field that affects the molecular distribution and forms adsorption films due to the adsorbate-adsorbent interaction potential. The surface tension of the discussed menisci, as well as at the boundaries between the vapor or liquid adsorbate and solid walls, is calculated from the excess free energy of the interface (according to Gibbs). The state of the coexisting phases “vapor in a pore” and “liquid in a pore” must satisfy the equality of chemical potentials, excluding the appearance of metastable states. Methods for calculating three types of two-phase surface tensions in a three-aggregate system and a method for localizing areas of three-phase contact, as well as a microscopic description of the molecular distributions and properties of these areas are outlined. The approach is demonstrated using the example of slit-like pores with smooth and rough walls, as well as cylindrical pores and their junctions between pores of different radii. The size effects of the contact angle are studied as a function of the geometry of the pore cross section and the potential of the pore walls. The results obtained are ahead of the level of existing published works.

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介孔体系中分子两相表面张力的三种类型及其计算方法

摘要在温度 T <Tc(H)（其中 Tc(H) 为临界温度，H 为特征孔径）下，所有介孔系统中吸附的吸附剂分子都会分离成 "孔中蒸气 "和 "孔中液体 "两种共存相。这种吸附分离的条件取决于孔隙宽度和吸附剂与吸附剂之间的相互作用能。在不同材料的孔隙中，吸附剂的分布在物质转移和建立平衡状态的过程中起着重要作用。分子的分离伴随着汽液界面半月板的形成。它们在很大程度上决定了多孔材料传质过程的总体阻力。关于汽液界面描述的最先进结果是在所谓的分子晶格-气体模型基础上获得的，该模型使得在过渡区域的异质分布模型中以同等精度计算分子分布成为可能。不可变形的孔壁会产生一个外部场，该场会影响分子分布，并由于吸附剂与吸附剂之间的相互作用势形成吸附膜。所讨论的孔壁以及蒸气或液体吸附剂与固体孔壁之间边界的表面张力是通过界面的过剩自由能计算得出的（根据吉布斯原理）。孔隙中的蒸气 "和 "孔隙中的液体 "共存相的状态必须满足化学势相等的条件，不包括出现蜕变态。本文概述了三聚体系中三种两相表面张力的计算方法、三相接触区域的定位方法以及这些区域的分子分布和性质的微观描述。该方法以具有光滑和粗糙孔壁的狭缝状孔隙、圆柱形孔隙及其不同半径孔隙之间的交界处为例进行了演示。研究了接触角的大小效应与孔隙横截面几何形状和孔壁电位的函数关系。所获得的结果领先于现有已发表的研究成果。

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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来源期刊

Nanotechnologies in Russia NANOSCIENCE & NANOTECHNOLOGY-

CiteScore

1.20

自引率

0.00%

发文量

期刊介绍： Nanobiotechnology Reports publishes interdisciplinary research articles on fundamental aspects of the structure and properties of nanoscale objects and nanomaterials, polymeric and bioorganic molecules, and supramolecular and biohybrid complexes, as well as articles that discuss technologies for their preparation and processing, and practical implementation of products, devices, and nature-like systems based on them. The journal publishes original articles and reviews that meet the highest scientific quality standards in the following areas of science and technology studies: self-organizing structures and nanoassemblies; nanostructures, including nanotubes; functional and structural nanomaterials; polymeric, bioorganic, and hybrid nanomaterials; devices and products based on nanomaterials and nanotechnology; nanobiology and genetics, and omics technologies; nanobiomedicine and nanopharmaceutics; nanoelectronics and neuromorphic computing systems; neurocognitive systems and technologies; nanophotonics; natural science methods in a study of cultural heritage items; metrology, standardization, and monitoring in nanotechnology.