Simulation of Small Molecules Permeation Through Polymer Matrix

IF 2.4 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY

Journal of Molecular and Engineering Materials Pub Date : 2016-12-01 DOI:10.1142/S2251237316400189

A. Fleury, Xu Li, A. Soldera

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Abstract

New technologies deeply depend on the ability of chemists to synthesize new functional materials. However, this synthetic step requires great efforts. Moreover, it is very likely that the ensuing compound does not fit the expected properties. With the advent of simulation, associated with the increase in computer performance and efficiency of codes, a screening of the best potential candidates to be synthesized becomes available. Accordingly, getting a polymer with a specific permeability, and also understanding the molecular reasons underlying this process, are some of the assets of molecular simulation. Nevertheless, representation of a material from a molecular perspective is not straightforward. A specific protocol must be established. It takes into account the fact that calculations are carried out on very tiny systems. An accurate depiction and perpetual validations confronting simulated results with experimental data make the protocol relevant. The computation of the penetrants’ diffusion coefficient and solubility is then introduced, in order to reveal the simulation of the permeation of a small molecule through an amorphous polymer system. The paper concludes with the most recent studies on the subject.

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聚合物基质中小分子渗透的模拟

新技术在很大程度上依赖于化学家合成新功能材料的能力。然而，这个合成步骤需要付出很大的努力。此外，所得到的化合物很可能不符合预期的性质。随着模拟技术的出现，以及计算机性能和代码效率的提高，筛选最佳的潜在候选对象进行合成成为可能。因此，获得具有特定渗透率的聚合物，并了解这一过程背后的分子原因，是分子模拟的一些资产。然而，从分子的角度来表示材料并不是直截了当的。必须建立一个具体的协议。它考虑到计算是在非常小的系统上进行的。模拟结果与实验数据的准确描述和持续验证使该协议具有相关性。然后介绍了渗透剂的扩散系数和溶解度的计算，以揭示小分子通过非晶聚合物体系渗透的模拟。这篇论文总结了关于这个问题的最新研究。

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

Journal of Molecular and Engineering Materials MATERIALS SCIENCE, MULTIDISCIPLINARY-

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