Alternative nonlocal descriptions of boundary-layer evolution
- Univ. of Wisconsin, Madison (United States)
Two alternative parameterizations for nonlocal turbulence mixing are tested in a 1D boundary-layer model against a dataset from the 1983 Boundary-Layer Experiment (BLX83) in Oklahoma. One method, proposed previously by Stull and Driedonks, is based on a nonlocal approximation to the turbulence kinetic energy (TKE) equation. An alternate method, based on a nonlocal approximation to the Richardson number, is simplified here from earlier parameterizations for transilient turbulence theory. Convective mixed-layer simulations of the vertical profiles of mean variables and fluxes using both methods are compared to the BLX83 observations and to simulations using a traditional slab model. The TKE method develops a surface layer that is too thick compared to BLX83 data, particularly in the early morning. It also lacks the subadiabatic lapse rate that is observed in the top of the mixed layer. The Richardson number approach produces more accurate mixed-layer profiles, but lacks the general physical interpretation of the TKE method. Nonlocal spectral decompositions of the flux and intensity of mixing confirm that large-size eddies dominate within the middle of the mixed layer. Based on this limited validation, the Richardson number method is recommended for convective boundary layers, but the TKE approach should be used for modeling more general boundary layers that can include clouds and stable and/or windy conditions. 19 refs., 22 figs.
- OSTI ID:
- 6779007
- Journal Information:
- Journal of the Atmospheric Sciences; (United States), Vol. 49:23; ISSN 0022-4928
- Country of Publication:
- United States
- Language:
- English
Similar Records
A Scale-Adaptive Turbulent Kinetic Energy Closure for the Dry Convective Boundary Layer
Exploring Stratocumulus Cloud-Top Entrainment Processes and Parameterizations by Using Doppler Cloud Radar Observations
Related Subjects
99 GENERAL AND MISCELLANEOUS//MATHEMATICS, COMPUTING, AND INFORMATION SCIENCE
ATMOSPHERIC CIRCULATION
BOUNDARY LAYERS
TURBULENCE
MATHEMATICAL MODELS
CLOUDS
CONVECTION
KINETIC ENERGY
OKLAHOMA
ONE-DIMENSIONAL CALCULATIONS
RICHARDSON NUMBER
WIND
DEVELOPED COUNTRIES
ENERGY
ENERGY TRANSFER
HEAT TRANSFER
LAYERS
MASS TRANSFER
NORTH AMERICA
USA
540110*
990200 - Mathematics & Computers