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Related Experiment Video

Updated: Jun 5, 2026

Surface Renewal: An Advanced Micrometeorological Method for Measuring and Processing Field-Scale Energy Flux Density Data
09:55

Surface Renewal: An Advanced Micrometeorological Method for Measuring and Processing Field-Scale Energy Flux Density Data

Published on: December 12, 2013

Spatial intermittency of surface layer wind fluctuations at mesoscale range.

Rachel Baïle1, Jean-François Muzy

  • 1SPE UMR 6134, CNRS, Université de Corse, Route des Sanguinaires, Vignola, 20000 Ajaccio, France. baile@univ-corse.fr

Physical Review Letters
|January 15, 2011
PubMed
Summary

Surface layer wind data from the Netherlands reveals spatial correlations that follow a single logarithmic curve. This finding suggests intermittent mesoscale fluctuations, similar to fully developed turbulence.

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Area of Science:

  • Meteorology
  • Atmospheric Science
  • Fluid Dynamics

Background:

  • Understanding wind patterns is crucial for various applications, including renewable energy and weather forecasting.
  • Previous studies have explored wind variability, but mesoscale intermittency requires further investigation.

Purpose of the Study:

  • To analyze spatial correlations in hourly surface layer wind data from the Netherlands.
  • To characterize the scaling properties of wind velocity increments and identify intermittency.
  • To compare mesoscale wind fluctuations with characteristics of fully developed turbulence.

Main Methods:

  • Analysis of hourly surface layer wind series from multiple sites in the Netherlands.
  • Calculation of velocity magnitude correlation coefficients as a function of spatial distance.
  • Study of spatial velocity increment structure functions and estimation of the ζ(q) spectrum.

Main Results:

  • Wind velocity correlation coefficients fall onto a single logarithmic curve with spatial distance.
  • The observed curve is well-described by a logarithmic shape, indicating continuous cascades.
  • An intermittency coefficient λ2 ≃ 0.04 and an integral scale L ≃ 600 km were estimated.
  • The study confirmed an intermittent nature of mesoscale fluctuations.

Conclusions:

  • Mesoscale wind fluctuations exhibit intermittent characteristics, analogous to fully developed turbulence.
  • The findings support the concept of continuous cascades in atmospheric flows.
  • The logarithmic correlation curve provides a valuable model for understanding spatial wind variability.