Litcius/Paper detail

The Statistics of Oceanic Turbulence Measurements. Part I: Shear Variance and Dissipation Rates

Rolf G. Lueck

2022Journal of Atmospheric and Oceanic Technology21 citationsDOIOpen Access PDF

Abstract

Abstract An empirically derived statistic is used to estimate the confidence interval of a dissipation estimate that uses a finite amount of shear data. Four collocated shear probes, mounted on a bottom anchored float, are used to measure the rate of dissipation of turbulence kinetic energy ϵ at a height of 15 m above the bottom in a 55 m deep tidal channel. One pair of probes measures ∂ w /∂ x while the other measures ∂ υ /∂ x , where w and υ are the vertical and lateral velocity. The shear-probe signals are converted into a regularly resampled space series to permit the rate of dissipation to be estimated directly from the variance of the shear using (and similarly for the υ component), for averaging lengths, L ranging from 1 to 10 4 Kolmogorov lengths. While the rate of dissipation fluctuates by more than a factor of 100, the fluctuations of the differences of between pairs of probes are stationary, zero mean, and distributed normally for averaging lengths of L = ∼30 to 10 4 Kolmogorov lengths. The variance of the differences, , scales as L −7/9 , independent of stratification for buoyancy Reynolds numbers larger than ∼600, and for dissipation rates from ∼10 −10 to ∼10 −5 W kg −1 . The variance decreases more slowly than L −1 because the averaging is done in linear space while the variance is evaluated in logarithmic space. This statistic provides the confidence interval of an ϵ estimate such as the 95% interval . This result also applies to the traditional ϵ estimates that are made by way of spectral integration, after L is adjusted for the truncation of the shear spectrum. Significance Statement The results reported here can be used to estimate the statistical uncertainty of a dissipation estimate that is derived from a finite length of turbulence shear data.

Topics & Concepts

DissipationTurbulenceStatisticsReynolds numberPhysicsTurbulence kinetic energyMathematicsStatistical physicsMeteorologyThermodynamicsReservoir Engineering and Simulation MethodsOceanographic and Atmospheric ProcessesMeteorological Phenomena and Simulations