拓扑链接驱动弱拉伸流中环状聚合物的异常增厚。
Topological Linking Drives Anomalous Thickening of Ring Polymers in Weak Extensional Flows.
作者信息
O'Connor Thomas C, Ge Ting, Rubinstein Michael, Grest Gary S
机构信息
Sandia National Laboratories, Albuquerque, New Mexico 87185, USA.
Department of Mechanical Engineering and Materials Science, Duke University, Durham, North Carolina 27708, USA.
出版信息
Phys Rev Lett. 2020 Jan 17;124(2):027801. doi: 10.1103/PhysRevLett.124.027801.
Abstract
Molecular dynamics simulations confirm recent extensional flow experiments showing ring polymer melts exhibit strong extension-rate thickening of the viscosity at Weissenberg numbers Wi≪1. Thickening coincides with the extreme elongation of a minority population of rings that grows with Wi. The large susceptibility of some rings to extend is due to a flow-driven formation of topological links that connect multiple rings into supramolecular chains. Links form spontaneously with a longer delay at lower Wi and are pulled tight and stabilized by the flow. Once linked, these composite objects experience larger drag forces than individual rings, driving their strong elongation. The fraction of linked rings depends nonmonotonically on Wi, increasing to a maximum when Wi∼1 before rapidly decreasing when the strain rate approaches 1/τ_{e}.
摘要
分子动力学模拟证实了最近的拉伸流动实验,该实验表明环状聚合物熔体在魏森贝格数Wi≪1时表现出强烈的粘度拉伸速率增稠现象。增稠与少数环状物群体的极端伸长相吻合,该群体随Wi增大而增长。一些环对伸长的高敏感性是由于流动驱动形成了拓扑连接,这些连接将多个环连接成超分子链。连接在较低的Wi下自发形成,延迟时间更长,并被流动拉紧并稳定下来。一旦连接,这些复合物体比单个环受到更大的阻力,从而驱动它们的强烈伸长。连接环的比例随Wi呈非单调变化,在Wi∼1时增加到最大值,然后在应变速率接近1/τ_{e}时迅速下降。
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