Topological Transitions in Liquid/Liquid Interfaces

J. Lowengrub, J. Goodman, H. Lee, E. Longmire, M. Shelley, L. Truskinovsky
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引用次数: 6

Abstract

A set of fundamental yet ill understood phenomena in uid dynamics involves changes in the topology of interfaces between partially miscible or nominally immiscible uids Such changes occur for example when continuous jets pinch o into droplets when sheared interfaces atomize and when droplets of one uid reconnect with one another These topological transitions occur in many practical applications involving transport mixing and separation of petroleum chemical and food products as well as contaminated waste streams The dynamics of topological transitions are di cult to understand and model for several reasons For one the uids in which these transitions occur are complex A second problem associated with topological transitions is caused by the short time scales over which they occur In practical ows the transition time scales are much shorter than the local ow time scales making the transitions di cult to characterize experimentally or compute numerically A third problem associated with transitions is purely numerical how does one handle the change in interface topology in a physically justi ed way In this paper we will address the last problem in the context of incompressible uid ows Many researchers see for example have tried using ad hoc methods to change the topology of interfaces While this approach often referred to as contour surgery allows topological transitions to be overcome it is di cult to justify the reconnection conditions based on physical principles In a few special cases involving uid gas interfaces it is possible to develop physically based reconnection conditions by using special similarity solutions of the Navier Stokes equations see For ows involving liquid liquid interfaces however the dynamics are more complicated and no such similarity solutions have been constructed
液/液界面中的拓扑跃迁
流体动力学中有一组基本但尚未被理解的现象,涉及部分混溶或名义上不混溶的流体之间界面拓扑结构的变化,例如,当剪切界面发生雾化时,当连续射流挤压成液滴时,以及当一种流体的液滴彼此重新连接时,就会发生这种变化。这些拓扑结构的转变发生在许多实际应用中,包括石油、化工和食品产品的输送、混合和分离由于几个原因,拓扑转换的动力学很难理解和建模,首先,这些转换发生的流体是复杂的,与拓扑转换相关的第二个问题是由它们发生的时间尺度短引起的,在实际中,转换时间尺度比局部低时间尺度短得多,使得转换无法用实验或数值计算来表征与转换是纯粹的数值如何处理接口拓扑的变化身体justi ed的方法在本文中,我们将讨论的最后一个问题的背景下不可压缩uid ows许多研究人员看到例如试图使用临时改变接口的拓扑方法,这种方法通常被称为轮廓手术可以克服它是拓扑转换di崇拜来证明基于物理的重新连接条件在一些涉及流体气体界面的特殊情况下,可以通过使用Navier Stokes方程的特殊相似解来开发基于物理的重联条件(参见对于涉及液-液界面的流体),但是动力学更为复杂,没有构建这样的相似解
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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