聚合物的分子降解

K. L. Devries, M. Igarashi, F. Chao
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引用次数: 2

摘要

了解力或应力通过物体的分子(或原子)网络的传递不仅有助于预测材料的承载能力,而且还可能提供有关如何改变结构以增强性能的信息。在聚合物中,分子对机械性能的理解尤其困难,因为分子量、弹性、结晶度、网络的存在、取向等因素可能会产生影响。在任何一类材料中,物理结构的复杂性都比聚合物更为重要。化学结构非常相似但物理结构不同的聚合物,其物理性质可能相差数量级。如果能有方法探测聚合物结构在加载和破坏过程中发生的分子和原子事件,这显然是有帮助的。用于此目的的仪器包括:(1)电子自旋共振(ESR)监测均裂链断裂产生的自由基产生,(2)傅立叶变换红外光谱(FTIR)测量分子链断裂产生的新端基,(3)特性粘度或凝胶渗透色谱(GPC)检测伴随分子降解的分子量变化(MWC)。本报告将讨论并比较这些方法的研究结果。将特别强调最近的研究,其中使用计算机建模来识别ESR光谱,并比较ESR、FTIR和MWC对聚苯乙烯获得的结果。
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Molecular degradation of polymers

An understanding of the transmittal of force or stress through the molecular (or atomic) network of a body should not only be helpful in predicting the load carrying capability of materials but might also provide information on how structure can be altered to enhance properties. A molecular understanding of mechanical properties is particularly difficult in polymers where such factors as molecular weight, tacticity, crystallinity, presence of networks, orientation, etc., may have an influence. In no class of materials are intricacies of physical structure more important than in polymers. Polymers with very similar chemical structures but differing physical structure can have physical properties differing by orders of magnitude. It would obviously be helpful to have means to probe molecular and atomic events and occur during the loading and destruction of the polymer structure. Instruments that have been used for this purpose include: (1) electron spin resonance (ESR) to monitor free radical production resulting from homolytic chain scission, (2) Fourier transform infrared spectroscopy (FTIR) to measure new end groups resulting from molecular chain rupture, and (3) intrinsic viscosity or gel permeation chromotography (GPC) to detect molecular weight changes (MWC) accompanying molecular degradation. This presentation will discuss and compare research results from these methods. Particular emphasis will be placed on recent studies in which computer modeling has been used to identify ESR spectra and a comparison of the results obtained by ESR, FTIR, and MWC for polystyrene.

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