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QG–DL–Ekman: Dynamics of a Diabatic Layer in the Quasi-Geostrophic Framework

QG–DL–Ekman: Dynamics of a Diabatic Layer in the Quasi-Geostrophic Framework AbstractQuasigeostrophic (QG) theory describes the dynamics of synoptic-scale flows in the troposphere that are balanced with respect to both acoustic and internal gravity waves. Within this framework, effects of (turbulent) friction near the ground are usually represented by Ekman layer theory. The troposphere covers roughly the lowest 10 km of the atmosphere while Ekman layer heights are typically just a few hundred meters. However, this two-layer asymptotic theory does not explicitly account for substantial changes of the potential temperature stratification due to diabatic heating associated with cloud formation or with radiative and turbulent heat fluxes which can be significant in about the lowest 3 km and in the middle latitudes. To address this deficiency, this paper extends the classical QG–Ekman layer model by introducing an intermediate dynamically and thermodynamically active layer, called the “diabatic layer” (DL) from here on. The flow in this layer is also in acoustic, hydrostatic, and geostrophic balance but, in contrast to QG flow, variations of potential temperature are not restricted to small deviations from a stable and time-independent background stratification. Instead, within the DL diabatic processes are allowed to affect the leading-order stratification. As a consequence, this layer modifies the pressure field at the top of the Ekman layer, and with it the intensity of Ekman pumping seen by the quasigeostrophic bulk flow. The result is the proposed extended quasigeostrophic three-layer QG–DL–Ekman model for midlatitude dynamics. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Journal of the Atmospheric Sciences American Meteorological Society

QG–DL–Ekman: Dynamics of a Diabatic Layer in the Quasi-Geostrophic Framework

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Publisher
American Meteorological Society
Copyright
Copyright © American Meteorological Society
ISSN
1520-0469
eISSN
1520-0469
DOI
10.1175/jas-d-21-0110.1
Publisher site
See Article on Publisher Site

Abstract

AbstractQuasigeostrophic (QG) theory describes the dynamics of synoptic-scale flows in the troposphere that are balanced with respect to both acoustic and internal gravity waves. Within this framework, effects of (turbulent) friction near the ground are usually represented by Ekman layer theory. The troposphere covers roughly the lowest 10 km of the atmosphere while Ekman layer heights are typically just a few hundred meters. However, this two-layer asymptotic theory does not explicitly account for substantial changes of the potential temperature stratification due to diabatic heating associated with cloud formation or with radiative and turbulent heat fluxes which can be significant in about the lowest 3 km and in the middle latitudes. To address this deficiency, this paper extends the classical QG–Ekman layer model by introducing an intermediate dynamically and thermodynamically active layer, called the “diabatic layer” (DL) from here on. The flow in this layer is also in acoustic, hydrostatic, and geostrophic balance but, in contrast to QG flow, variations of potential temperature are not restricted to small deviations from a stable and time-independent background stratification. Instead, within the DL diabatic processes are allowed to affect the leading-order stratification. As a consequence, this layer modifies the pressure field at the top of the Ekman layer, and with it the intensity of Ekman pumping seen by the quasigeostrophic bulk flow. The result is the proposed extended quasigeostrophic three-layer QG–DL–Ekman model for midlatitude dynamics.

Journal

Journal of the Atmospheric SciencesAmerican Meteorological Society

Published: Mar 16, 2022

References

  • Rain. Glossary of Meteorology
  • Effects of moisture in a two-layer model of the midlatitude jet stream
    Bembenek, E.; Straub, D. N.; Merlis, T. M.
  • Will extratropical storms intensify in a warmer climate?
    Bengtsson, L.; Hodges, K. I.; Keenlyside, N.
  • Planetary geostrophic equations for the atmosphere with evolution of the barotropic flow
    Dolaptchiev, S. I.; Klein, R.
  • A proposal for the intercomparison of atmospheric general circulation models
    Held, I. M.; Suarez, M. J.
  • The ERA5 global reanalysis
    Hersbach, H.
  • Asymptotics for moist deep convection I: Refined scalings and self-sustaining updrafts
    Hittmeir, S.; Klein, R.
  • On the use and significance of isentropic potential vorticity maps
    Hoskins, B. J.; McIntyre, M. E.; Robertson, A. W.
  • A simple multicloud parameterization for convectively coupled tropical waves. Part I: Linear analysis
    Khouider, B.; Majda, A. J.
  • Scale-dependent asymptotic models for atmospheric flows
    Klein, R.
  • A quasi-geostrophic model for moist storm tracks
    Laîné, A.; Lapeyre, G.; Riviére, G.
  • Moist versus dry barotropic instability in a shallow-water model of the atmosphere with moist convection
    Lambaerts, J.; Lapeyre, G.; Zeitlin, V.
  • Moist versus dry baroclinic instability in a simplified two-layer atmospheric model with condensation and latent heat release
    Lambaerts, J.; Lapeyre, G.; Zeitlin, V.
  • Stochastic and mesoscopic models for tropical convection
    Majda, A. J.; Khouider, B.
  • Energy decompositions for moist Boussinesq and anelastic equations with phase changes
    Marsico, D. H.; Smith, L. M.; Stechmann, S. N.
  • Cloud properties and associated radiative heating rates in the tropical western Pacific
    Mather, J. H.; McFarlane, S. A.; Miller, M. A.; Johnson, K. L.
  • A balanced state consistent with planetary-scale motion for quasi-geostrophic dynamics
    Moon, W.; Cho, J.
  • Multiscale asymptotics analysis for the mesoscale dynamics of cloud-topped boundary layers
    Owinoh, A.; Stevens, B.; Klein, R.
  • Motion and structure of atmospheric mesoscale baroclinic vortices: Dry air and weak environmental shear
    Päschke, E.; Marschalik, P.; Owinoh, A.; Klein, R.
  • The dynamics of heat lows
    Rácz, Z.; Smith, R.
  • Precipitating quasigeostrophic equations and potential vorticity inversion with phase changes
    Smith, L.; Stechmann, S. N.
  • Atmospheric moist convection
    Stevens, B.
  • Estimation of atmospheric mixing layer height from radiosonde data
    Wang, X. Y.; Wang, K. C.
  • Balanced and unbalanced components of moist atmospheric flows with phase changes
    Wetzel, A. N.; Smith, L. M.; Stechmann, S. N.; Martin, J. E.
  • On the relationship between stratiform low cloud cover and lower-tropospheric stability
    Wood, R.; Bretherton, C. S.
  • Relationship between marine boundary layer clouds and lower tropospheric stability observed by AIRS, CloudSat, and CALIOP
    Yue, Q.; Kahn, B. H.; Fetzer, E. J.; Teixeira, J.
  • Relationships between outgoing longwave radiation and diabatic heating in reanalyses
    Zhang, K.; Randel, W. J.; Fu, R.