聚合物焊接的蒙特卡罗模拟

K.R Haire, A.H Windle
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引用次数: 16

摘要

随机聚合物链的蒙特卡罗建模,在立方F晶格上的过程,提供了监测长范围弛豫过程和长达400个单位的链的动态参数的能力。该模型由Haire等人(Haire KR, Carver TJ, Windle AH)描述并验证。密集聚合物体系及其联锁的蒙特卡罗模型与分子动力学模拟。计算与理论高分子科学2000;在这里,应用于研究不同类型表面附近的分子参数,也应用于聚合物焊接过程,其中两个相邻表面之间的粘附是通过穿过表面的链的相互渗透来实现的。该模型表明,表面扭曲了与其相邻的链的构象,从而形成一个扁平的分子包膜,空位和链端的浓度在表面附近增加,而在亚表面区域,代表链质心的点的密度增加。这些结果证实了先前的预测,并为模型提供了额外的信心。焊接过程的建模导致了固有焊接时间tw的参数,即从表面最初的完美接触到实现焊缝内链构象与整体无法区分的时间。在配合表面粗化的初始阶段后,按照重复理论预测的t1/4规律进行焊接。跨越边界到达给定相互扩散水平的时间与链长l成正比,这是一种相对弱的依赖关系,而tw与链长l3成正比,这是一种强依赖关系。这与链端到端向量的弛豫时间对长度的依赖相同。事实上,在体模型上测量的弛豫时间和tw之间的一致性是惊人的接近,至少对于这里所研究的单分散聚合物是如此。
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Monte Carlo simulation of polymer welding

Monte Carlo Modelling of random polymer chains, course grained onto a cubic F lattice, provides the ability to monitor the long range relaxation processes and the dynamic parameters of chains up to 400 units long. The model, described and verified by Haire et al. (Haire KR, Carver TJ, Windle AH. A Monte Carlo model for dense polymer systems and its interlocking with molecular dynamics simulation. Computational and Theoretical Polymer Science 2000; in press), is here applied to the study of molecular parameters in the vicinity of different types of surface and also to the process of polymer welding, whereby adhesion between two adjacent surfaces is achieved by the interpenetration of chains which are across the surface.

The model demonstrates that a surface distorts the conformation of chains adjacent to it to give an oblate molecular envelope, that the concentration of vacant sites and chain ends increases near to the surface and that the density of points representing the centres of mass of the chains increases in the sub-surface regions. These results confirm earlier predictions and provide additional confidence in the model.

Modelling of the welding process leads to the parameter intrinsic weld time, tw, which is the time from initial perfect contact of the surfaces to the achievement of a weld within which the chain conformation is indistinguishable from the bulk. After the initial period in which the mating surfaces roughen, the welding proceeds according to the t1/4 law predicted by reptation theory. The time to a given level of interdiffusion across the boundary is proportional to the chain length l, a comparatively weak dependence, while tw is proportional to l3, a strong dependence. This is the same dependence on length as for the relaxation time of the chain end-to-end vectors. In fact, the agreement between the relaxation time, measured on the model of the bulk, and tw is surprisingly close, at least for the monodisperse polymers investigated here.

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