Classifying Amorphous Polymers for Membrane Technology Basing on Accessible Surface Area of Their Conformations

Q3 Engineering

Advances in Systems Science and Applications Pub Date : 2020-09-30 DOI:10.25728/ASSA.2020.20.3.897

O. Miloserdov

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引用次数: 2

Abstract

Almost 400 amorphous polymer materials used in membrane gas separation technology are clustered on the basis of the shape of their polymer chains conformations. Obtained clusters, which rely solely on the geometry of polymer chains and not on the chemical class (polyamides, polyacetylenes, etc.), are shown to discriminate polymers with respect to their transport properties, in particular, the coefficient of diffusion. The method proposed consists of several steps. Firstly, realistic conformations of large polymer macromolecules are constructed using the program code developed in the RDKit environment for Python. Then, polymer conformations are characterized by a curve that relates the “accessible surface area” (i.e., the contact surface between the spherical model of a macromolecule and a spherical “probe”) to the radius of this probe, and also seven similar curves, which relate the polarized (neutral, positively or negatively charged, etc.) accessible surface area to the radius of the spherical probe that represents the variety of penetrant gases. An improved algorithm for surface area calculation maps out the outer surface of the macromolecule to eliminate its influence. The curves are averaged between ten polymer conformations to obtain more robust figures. Finally, agglomerative clustering is used to separate different polymers in the space of these curves that align their accessible-surface-area-related quantities against the probe radius. The proposed classification of polymers can be used to develop more precise predictive models of polymers’ transport properties for the theory-guided and computer-aided materials design.

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基于构象的可及表面积对膜技术中的非晶态聚合物进行分类

近400种用于膜气体分离技术的非晶态聚合物材料是根据其聚合物链构象的形状聚集在一起的。所获得的簇仅依赖于聚合物链的几何形状，而不依赖于化学类别(聚酰胺、聚乙炔等)，可以根据聚合物的输运性质，特别是扩散系数来区分它们。所提出的方法包括几个步骤。首先，使用在Python的RDKit环境中开发的程序代码构建大型聚合物大分子的实际构象。然后，聚合物构象的特征是一条“可接近表面积”(即大分子的球形模型与球形“探针”之间的接触面)与该探针半径的曲线，以及七条类似的曲线，这些曲线将极化(中性、带正电或带负电等)可接近表面积与代表各种渗透气体的球形探针的半径联系起来。一种改进的表面积计算算法绘制出大分子的外表面以消除其影响。这些曲线在十种聚合物构象之间进行平均，以获得更可靠的数据。最后，使用聚集聚类来分离这些曲线空间中的不同聚合物，这些曲线将其可达表面积相关数量与探针半径对齐。提出的聚合物分类方法可用于建立更精确的聚合物输运特性预测模型，用于理论指导和计算机辅助材料设计。

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

Advances in Systems Science and Applications Engineering-Engineering (all)

CiteScore

1.20

自引率

0.00%

发文量

期刊介绍： Advances in Systems Science and Applications (ASSA) is an international peer-reviewed open-source online academic journal. Its scope covers all major aspects of systems (and processes) analysis, modeling, simulation, and control, ranging from theoretical and methodological developments to a large variety of application areas. Survey articles and innovative results are also welcome. ASSA is aimed at the audience of scientists, engineers and researchers working in the framework of these problems. ASSA should be a platform on which researchers will be able to communicate and discuss both their specialized issues and interdisciplinary problems of systems analysis and its applications in science and industry, including data science, artificial intelligence, material science, manufacturing, transportation, power and energy, ecology, corporate management, public governance, finance, and many others.