A model for diffusion in a glassy polymer

W.R Vieth, K.J Sladek
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引用次数: 289

Abstract

A new technique for estimating diffusion rates in solid materials from transient sorption data was developed and applied to the diffusion of gases in polymer films. Specifically, the analysis developed here applies to solutes which are sorbed according to a particular isotherm: one described by a linear component (Henry's law) and a commonly observed nonlinear component (Langmuir equation). The linear component corresponds physically to gas dissolved in the amorphous regions of the polymer; the nonlinear, to gas trapped in polymer microvoids, analogous to the adherence of gas molecules to sites on the surface of porous adsorbents.

By using this equilibrium isotherm together with the assumptions that the gas trapped in microvoids is immobilized, and that the driving force for diffusion is the concentration gradient of dissolved molecules, a mathematical description of transient sorption was developed; this diffusion model consisted of a nonlinear partial differential equation. With the use of a finite-difference technique, solutions to the equation were obtained; these were next applied to data for the solution of CO2 in a one mil “Mylar” polyester film at 40°C. The diffusivity was estimated to be 1.74 × 10−9 cm.2/sec. and the precision of the method was estimated at ±12%.

In summary, the method developed has been successfully applied, and the proposed diffusion mechanism was thereby validated. It is believed that this method has wide potential applicability not only to the study of diffusion in polymers but also to the measurement of effective diffusivities of gases in porous catalysts.

玻璃状聚合物中的扩散模型
提出了一种利用瞬态吸附数据估计固体材料中扩散速率的新方法,并将其应用于聚合物薄膜中气体的扩散。具体地说,这里发展的分析适用于根据特定等温线吸附的溶质:一个由线性分量(亨利定律)描述,一个由通常观察到的非线性分量(朗缪尔方程)描述。线性组分在物理上对应于溶解在聚合物非晶区中的气体;聚合物微孔中的非线性气体,类似于气体分子附着在多孔吸附剂表面的位置。利用这一平衡等温线,并假设被困在微孔中的气体是固定的,扩散的驱动力是溶解分子的浓度梯度,建立了瞬态吸附的数学描述;该扩散模型由一个非线性偏微分方程组成。利用有限差分技术,得到了方程的解;接下来,将这些数据应用于40°C下1 mil“Mylar”聚酯薄膜中CO2溶液的数据。扩散系数估计为1.74 × 10−9 cm.2/sec。估计该方法的精密度为±12%。综上所述,所开发的方法已成功应用,并由此验证了所提出的扩散机制。认为该方法不仅适用于聚合物扩散的研究,而且适用于多孔催化剂中气体有效扩散系数的测定。
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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