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流动在重联涡旋线和纽结中跨尺度保持螺旋度守恒。

Helicity conservation by flow across scales in reconnecting vortex links and knots.

机构信息

James Franck Institute, Department of Physics, and

School of Mathematics, University of East Anglia, Norwich Research Park, Norwich NR4 7TJ, United Kingdom.

出版信息

Proc Natl Acad Sci U S A. 2014 Oct 28;111(43):15350-5. doi: 10.1073/pnas.1407232111. Epub 2014 Oct 17.

DOI:10.1073/pnas.1407232111
PMID:25326419
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4217404/
Abstract

The conjecture that helicity (or knottedness) is a fundamental conserved quantity has a rich history in fluid mechanics, but the nature of this conservation in the presence of dissipation has proven difficult to resolve. Making use of recent advances, we create vortex knots and links in viscous fluids and simulated superfluids and track their geometry through topology-changing reconnections. We find that the reassociation of vortex lines through a reconnection enables the transfer of helicity from links and knots to helical coils. This process is remarkably efficient, owing to the antiparallel orientation spontaneously adopted by the reconnecting vortices. Using a new method for quantifying the spatial helicity spectrum, we find that the reconnection process can be viewed as transferring helicity between scales, rather than dissipating it. We also infer the presence of geometric deformations that convert helical coils into even smaller scale twist, where it may ultimately be dissipated. Our results suggest that helicity conservation plays an important role in fluids and related fields, even in the presence of dissipation.

摘要

在流体力学中,旋度(或纽结)是一个基本守恒量的猜想有着丰富的历史,但在存在耗散的情况下,这种守恒的性质一直难以解决。我们利用最近的进展,在粘性流体和模拟超流体中制造涡旋纽结和链接,并通过拓扑变化的重连来跟踪它们的几何形状。我们发现,通过重连重新连接涡旋线,能够将纽结和链接中的旋度转移到螺旋线圈中。由于重连的涡旋自动采用了相反的方向,因此这个过程非常有效。使用一种新的方法来量化空间旋度谱,我们发现,重连过程可以看作是在尺度之间传递旋度,而不是耗散它。我们还推断出存在几何变形,将螺旋线圈转化为更小尺度的扭曲,最终可能在那里耗散。我们的结果表明,即使在存在耗散的情况下,旋度守恒在流体和相关领域中也起着重要的作用。

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本文引用的文献

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