Lifetime prediction for polymer coatings via thermogravimetric analysis

IF 2.3 4区 材料科学 Q2 CHEMISTRY, APPLIED
Andrei A. Stolov, Matthew Popelka, Jesse A. Caviasca
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Abstract

Polymer coatings, when brought to elevated temperatures may experience thermal decomposition, leading to failure of their protective properties. The process of thermal decomposition can be followed by thermogravimetry (TG), which allows quantitative analysis. Applying the right theoretical model, the TG data can be extrapolated to a broader temperature range for evaluating the coating’s lifetime. The paper provides a thorough analysis of the current-state experimental and theoretical approaches in this area. As an example, thermal decomposition in nitrogen, air, and oxygen of dual polymer coatings on two different optical fibers is studied via isothermal and non-isothermal TG. For one of the coatings, the isothermal mass loss behavior resembles an n-th order kinetics function. For the other coating, the TG curves exhibit a more complex behavior, suggesting presence of an antioxidant in the chemical composition. From the non-isothermal TG data, using isoconversional Flynn–Wall–Ozawa, Kissinger–Akahira–Sunose and advanced Vyazovkin, Farjas–Roura and Budrugeac approaches, the activation energies are determined, and the isothermal mass loss functions are simulated. For several fiber/gas combinations, a significant discrepancy is observed between the experimentally obtained isothermal TG curves and those simulated from the non-isothermal data. The noted disagreement is analyzed in a view of miscellaneous assumptions of the advanced simulation methods, including the basic isoconversion principle. It is concluded that the isoconversional approaches are not applicable to the studied complex systems, and that the isothermal TG method should be used for determining the coating lifetime at elevated temperatures.

Abstract Image

通过热重分析预测聚合物涂层的使用寿命
聚合物涂层在高温下可能会发生热分解,导致其保护性能失效。热重仪 (TG) 可以跟踪热分解过程,并进行定量分析。应用正确的理论模型,可以将 TG 数据推断到更宽的温度范围,以评估涂层的使用寿命。本文对该领域的实验和理论方法现状进行了深入分析。例如,通过等温和非等温 TG 研究了两种不同光纤上的双聚合物涂层在氮气、空气和氧气中的热分解。其中一种涂层的等温质量损失行为类似于 n 阶动力学函数。而另一种涂层的 TG 曲线则表现得更为复杂,表明其化学成分中含有抗氧化剂。根据非等温 TG 数据,使用等转换 Flynn-Wall-Ozawa、Kissinger-Akahira-Sunose 和高级 Vyazovkin、Farjas-Roura 和 Budrugeac 方法,确定了活化能,并模拟了等温质量损失函数。对于几种纤维/气体组合,实验得出的等温 TG 曲线与根据非等温数据模拟得出的曲线之间存在显著差异。分析发现的差异与先进模拟方法的各种假设有关,其中包括基本等容原理。结论是等温转换方法不适用于所研究的复杂系统,应使用等温 TG 方法确定涂层在高温下的使用寿命。
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来源期刊
Journal of Coatings Technology and Research
Journal of Coatings Technology and Research 工程技术-材料科学:膜
CiteScore
4.30
自引率
8.70%
发文量
130
审稿时长
2.5 months
期刊介绍: Journal of Coatings Technology and Research (JCTR) is a forum for the exchange of research, experience, knowledge and ideas among those with a professional interest in the science, technology and manufacture of functional, protective and decorative coatings including paints, inks and related coatings and their raw materials, and similar topics.
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