Litcius/Paper detail

Detecting Nonequilibrium States in Atmospheric Turbulence

Marta Wacławczyk, Jakub Nowak, Holger Siebert, Szymon P. Malinowski

2022Journal of the Atmospheric Sciences22 citationsDOIOpen Access PDF

Abstract

Abstract In this work we show how to retrieve information about temporal changes of turbulence in the atmosphere based on in situ wind velocity measurements performed by aircraft. We focus on the stratocumulus-topped boundary layer high-resolution data taken by a helicopter-borne platform Airborne Cloud Turbulence Observation System (ACTOS). We calculate two nondimensional indicators, the dissipation factor and the integral-to-Taylor-scale ratio, and study their dependence on the Taylor-scale-based Reynolds number. By analyzing these results, we can identify regions where turbulence is in its stationary state and regions where turbulence decays in time or, on the contrary, becomes stronger. We can also detect nonequilibrium turbulence states, which indicate the presence of rapidly changing external conditions. Significance Statement The purpose of this work is to retrieve new information on turbulence in the atmosphere. We consider data from a field study based on in situ observations from a measurement payload below a slow-flying helicopter. We show that it is possible to retrieve information on temporal tendencies in a given region from such measurements. We attempt to estimate whether turbulence is in its stationary state, or possibly, turbulence decays due to insufficient production, or, on the contrary, becomes stronger. Such information provide useful knowledge of small-scale processes in the atmospheric boundary layer and can be used to improve their parameterizations.

Topics & Concepts

TurbulencePhysicsK-epsilon turbulence modelK-omega turbulence modelTurbulence kinetic energyMeteorologyPlanetary boundary layerBoundary layerScale (ratio)Clear-air turbulenceAtmosphere (unit)Non-equilibrium thermodynamicsMechanicsStatistical physicsEnvironmental scienceComputational physicsThermodynamicsQuantum mechanicsAtmospheric aerosols and cloudsPlant Water Relations and Carbon DynamicsWind and Air Flow Studies