Phase-field simulations of morphology development in reactive polymer blending

IF 3 2区工程技术 Q2 MECHANICS

Journal of Rheology Pub Date : 2023-01-01 DOI:10.1122/8.0000523

R. Sengupta, Mukul D. Tikekar, James V. Raj, K. Delaney, Michael C. Villet, G. Fredrickson

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引用次数: 1

Abstract

Reactive blending is an efficient method for synthesizing polymer blends. Industrially, this process is carried out in extruders, where the reacting polymers and the generated copolymer are subjected to high shear stresses. The dynamics of the process, and the resulting morphology is dictated by a coupling of the hydrodynamic forces in the extruder, the thermodynamic interactions between species, and the reaction kinetics on a complex interfacial manifold. We use phase-field simulations to quantify the evolution of the reactive blending process under an external shear flow. Specifically, we consider a model system of two homopolymers of equal length, which react via an end-coupling reaction to form a diblock copolymer of double the length. We compare the morphology development in two different initial geometries of the homopolymers—a cylindrical thread and a drop of one homopolymer in a matrix of the second. We investigate the effect of flow strength, measured by the shear rate, and reaction kinetics, quantified by a Damkohler number, on the progress of the reaction and morphology development. Cylindrical threads are susceptible to breakup via the Rayleigh capillary instability. We demonstrate that this instability can be suppressed by imposing shear along the direction of the thread and increasing the extent of the reaction. The reaction rate in this geometry is unaffected by shear imposed along the cylinder axis. Drops deform significantly under an imposed flow, eventually stretching to long cylindrical threads for sufficient shear rates. In the case of drops, shear stresses enhance the reaction rate by deforming the drop, enabling more homopolymers to come in contact at the expanded interface. We show that shear stresses significantly impact the morphology development and reaction dynamics in reactive polymer blending.

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反应性聚合物共混过程中形态发展的相场模拟

反应共混是合成聚合物共混物的一种有效方法。工业上，这一过程是在挤出机中进行的，其中反应聚合物和生成的共聚物受到高剪切应力。该过程的动力学和最终的形态是由挤出机中的流体动力耦合、物种之间的热力学相互作用和复杂界面流形上的反应动力学决定的。我们使用相场模拟来量化在外部剪切流作用下反应混合过程的演变。具体来说，我们考虑了一个由两种等长均聚物组成的模型体系，它们通过端偶联反应形成两倍长度的双嵌段共聚物。我们比较了均聚物在两种不同初始几何形态下的形态发展——圆柱螺纹和一种均聚物滴在另一种均聚物的矩阵中。我们研究了流动强度(用剪切速率来衡量)和反应动力学(用Damkohler数来量化)对反应进展和形态发展的影响。圆柱螺纹容易因瑞利毛细不稳定性而断裂。我们证明，这种不稳定性可以通过沿螺纹方向施加剪切和增加反应的程度来抑制。这种几何结构的反应速率不受沿圆柱体轴施加的剪切的影响。液滴在施加的流量下显著变形，最终拉伸成足够剪切速率的长圆柱形螺纹。在液滴的情况下，剪切应力通过使液滴变形来提高反应速率，使更多的均聚物在扩展的界面上接触。研究表明，剪切应力对反应性聚合物共混过程中的形态发育和反应动力学有显著影响。

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来源期刊

Journal of Rheology 物理-力学

CiteScore

6.60

自引率

12.10%

发文量

100

审稿时长

1 months

期刊介绍： The Journal of Rheology, formerly the Transactions of The Society of Rheology, is published six times per year by The Society of Rheology, a member society of the American Institute of Physics, through AIP Publishing. It provides in-depth interdisciplinary coverage of theoretical and experimental issues drawn from industry and academia. The Journal of Rheology is published for professionals and students in chemistry, physics, engineering, material science, and mathematics.