{"title":"From Semi-Flexible Polymers to Membranes: Anomalous Diffusion and Reptation","authors":"R. Granek","doi":"10.1051/JP2:1997214","DOIUrl":null,"url":null,"abstract":"The dynamics of semi-flexible polymers and membranes is discussed. The effect of thermal undulations on both the transversal and longitudinal Mean Square Displacement (MSD) of a tagged monomer is studied in free polymers and membranes. The two MSDs are found to be proportional to one another, and behave as ∼ t 3/4 for polymers and ∼ t 2/3 for membranes on the short time scale. The longitudinal motion is shown to be linked to the dynamics of fluctuations of the projected length (area) of the polymer (membrane). We demonstrate how, at long times, these fluctuations lead to reptation motion of the polymer (membrane) in the longitudinal direction. We generalize this approach to investigate the motion of a membrane between two plates and a polymer in a tube. The latter problem is used as a model for polymer motion in semi-dilute solutions in which the persistence length is longer than the entanglement length. Such systems are not suitable for the classical reptation model of de-Gennes and of Doi and Edwards, which was designed for chains that are flexible on the entanglement distance. The reptation diffusion coefficient and relaxation times that we obtain have the same scaling with chain length L as in the classical reptation model, but differ greatly in factors that are dependent on the ratio of persistence length to entanglement length. We also discuss the diffusion of a tagged monomer under imposed tension and liquid crystalline order.","PeriodicalId":14774,"journal":{"name":"Journal De Physique Ii","volume":"1 1","pages":"1761-1788"},"PeriodicalIF":0.0000,"publicationDate":"1997-12-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"154","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal De Physique Ii","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1051/JP2:1997214","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 154
Abstract
The dynamics of semi-flexible polymers and membranes is discussed. The effect of thermal undulations on both the transversal and longitudinal Mean Square Displacement (MSD) of a tagged monomer is studied in free polymers and membranes. The two MSDs are found to be proportional to one another, and behave as ∼ t 3/4 for polymers and ∼ t 2/3 for membranes on the short time scale. The longitudinal motion is shown to be linked to the dynamics of fluctuations of the projected length (area) of the polymer (membrane). We demonstrate how, at long times, these fluctuations lead to reptation motion of the polymer (membrane) in the longitudinal direction. We generalize this approach to investigate the motion of a membrane between two plates and a polymer in a tube. The latter problem is used as a model for polymer motion in semi-dilute solutions in which the persistence length is longer than the entanglement length. Such systems are not suitable for the classical reptation model of de-Gennes and of Doi and Edwards, which was designed for chains that are flexible on the entanglement distance. The reptation diffusion coefficient and relaxation times that we obtain have the same scaling with chain length L as in the classical reptation model, but differ greatly in factors that are dependent on the ratio of persistence length to entanglement length. We also discuss the diffusion of a tagged monomer under imposed tension and liquid crystalline order.
讨论了半柔性聚合物和膜的动力学。在自由聚合物和膜中研究了热波动对标记单体横向和纵向均方位移(MSD)的影响。发现这两个msd彼此成正比,并且在短时间尺度上对聚合物表现为~ t 3/4,对膜表现为~ t 2/3。纵向运动显示与聚合物(膜)的投影长度(面积)波动的动力学有关。我们证明,在很长一段时间内,这些波动如何导致聚合物(膜)在纵向上的重复运动。我们推广这种方法来研究膜在两个板之间的运动和管中的聚合物。后一个问题被用作聚合物在半稀溶液中运动的模型,其中持续长度大于纠缠长度。这样的系统不适合de-Gennes和Doi和Edwards的经典重复模型,这些模型是为纠缠距离具有柔性的链设计的。我们得到的重复扩散系数和弛豫时间与经典重复模型的链长L有相同的标度,但依赖于持续长度与纠缠长度之比的因子差异很大。我们还讨论了标签单体在施加张力和液晶秩序下的扩散。