Abstract
Taylor’s frozen turbulence hypothesis is the central assumption invoked in most experiments designed to investigate turbulence physics with time resolving sensors. It is also frequently used in theoretical discussions when linking Lagrangian to Eulerian flow formalisms. In this work we seek to quantify the effectiveness of Taylor’s hypothesis on the field scale using water vapour as a passive tracer. A horizontally orientated Raman lidar is used to capture the humidity field in space and time above an agricultural region in Switzerland. High resolution wind speed and direction measurements are conducted simultaneously allowing for a direct test of Taylor’s hypothesis at the field scale. Through a wavelet decomposition of the lidar humidity measurements we show that the scale of turbulent motions has a strong influence on the applicability of Taylor’s hypothesis. This dependency on scale is explained through the use of dimensional analysis. We identify a ‘persistency scale’ that can be used to quantify the effectiveness of Taylor’s hypothesis, and present the accuracy of the hypothesis as a function of this non-dimensional length scale. These results are further investigated and verified through the use of large-eddy simulations.
Highlights
The Taylor frozen turbulence hypothesis (Taylor 1938) is universally prevalent in the investigation of fluid flow physics, as it is far more practical to deploy time-resolving instruments to track the temporal evolution of the fluid flow
In this paper we describe the Turbulent Atmospheric Boundary-layer, Lidar and Evaporation (TABLE) experiment that was designed, in part, to provide an appropriate test of Taylor’s hypothesis
In the present study we present a dataset obtained with a Raman lidar suitable for the analysis explained above, and use a wavelet approach to investigate the importance of eddy size on the applicability of Taylor’s hypothesis
Summary
The Taylor frozen turbulence hypothesis (Taylor 1938) is universally prevalent in the investigation of fluid flow physics, as it is far more practical to deploy time-resolving instruments to track the temporal evolution of the fluid flow. Keywords Atmospheric boundary layer · Humidity · Raman lidar · Taylor’s frozen turbulence hypothesis
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