Abstract
The evolving shape of material fluid lines in a flow underlies the quantitative prediction of the dissipation and material transport in many industrial and natural processes. However, collecting quantitative data on this dynamics remains an experimental challenge in particular in turbulent flows. Indeed the deformation of a fluid line, induced by its successive stretching and folding, can be difficult to determine because such description ultimately relies on often inaccessible multi-particle information. Here we report laboratory measurements in two-dimensional turbulence that offer an alternative topological viewpoint on this issue. This approach characterizes the dynamics of a braid of Lagrangian trajectories through a global measure of their entanglement. The topological length of material fluid lines can be derived from these braids. This length is found to grow exponentially with time, giving access to the braid topological entropy . The entropy increases as the square root of the turbulent kinetic energy and is directly related to the single-particle dispersion coefficient. At long times, the probability distribution of is positively skewed and shows strong exponential tails. Our results suggest that may serve as a measure of the irreversibility of turbulence based on minimal principles and sparse Lagrangian data.
Highlights
The evolving shape of material fluid lines in a flow underlies the quantitative prediction of the dissipation and material transport in many industrial and natural processes
Reynolds showed that watching the dynamics of coloured fluid lines in a flow was a powerful way to uncover the turbulent fabric of the underlying fluid motion[1]
This pioneering study provides a nice illustration that the problem of transport in turbulence is intimately connected to its Lagrangian description, the trajectory-based representation of hydrodynamics
Summary
The evolving shape of material fluid lines in a flow underlies the quantitative prediction of the dissipation and material transport in many industrial and natural processes. We report laboratory measurements in two-dimensional turbulence that offer an alternative topological viewpoint on this issue This approach characterizes the dynamics of a braid of Lagrangian trajectories through a global measure of their entanglement. Reynolds showed that watching the dynamics of coloured fluid lines in a flow was a powerful way to uncover the turbulent fabric of the underlying fluid motion[1] This pioneering study provides a nice illustration that the problem of transport in turbulence is intimately connected to its Lagrangian description, the trajectory-based representation of hydrodynamics. Despite the elegance of Reynolds approach, even unravelling the internal fluid motion in natural flows is not a trivial matter because the deformation of fluid lines is usually extremely convoluted[3,4] This observation is not intrinsic to turbulence. The application of mathematical tools from topology or dynamical system theory has been largely restricted to idealized maps or simple flow configurations[11,12,13,14]
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