On the Role of Sloping Terrain in the Forcing of the Great Plains Low-Level Jet

The summertime Great Plains low-level jet (LLJ) has been the subject of numerous investigations during the past several decades. Characteristics of the LLJ include nighttime development of a pronounced wind maximum of typically 15–20 m s−1 at levels 300–800 m above the surface and a clockwise rotati...

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Bibliographic Details
Published in:Journal of the atmospheric sciences 2010-08, Vol.67 (8), p.2690-2699
Main Authors: PARISH, Thomas R, OOLMAN, Larry D
Format: Article
Language:English
Subjects:
Ageostrophic winds
Boundary currents
Climatology
Cooling
Decoupling
Diurnal
Diurnal winds
Earth, ocean, space
Exact sciences and technology
External geophysics
Geostrophic flow
Geostrophic wind
Geostrophic winds
Heating
Heating and cooling
Horizontal
Inertial
Inertial oscillations
Low-level jets
Mathematical models
Meteorology
Night
Night-time
Nighttime
Oscillations
Physics of the high neutral atmosphere
Pressure distribution
Pressure field
Simulation
Terrain
Topography
Weather forecasting
Wind
Wind oscillations
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Summary:The summertime Great Plains low-level jet (LLJ) has been the subject of numerous investigations during the past several decades. Characteristics of the LLJ include nighttime development of a pronounced wind maximum of typically 15–20 m s−1 at levels 300–800 m above the surface and a clockwise rotation of the wind maximum during the course of the night. Maximum frequency of occurrence of the LLJ is found in the southern Great Plains. Theories proposed to explain the diurnal wind maximum of the Great Plains LLJ include inertial oscillation of the ageostrophic wind, the diurnal oscillation of the horizontal pressure field associated with heating and cooling of the sloping terrain, and the western boundary current interpretations. A simple equation system and output from the 12-km horizontal resolution Weather Research and Forecasting Nonhydrostatic Mesoscale Model (NAM) for July 2008 are used to provide evidence as to the importance of the Great Plains topography in driving the LLJ. Summertime heating of the sloping terrain is critical in establishing the climatological position for the Great Plains LLJ. Heating enhances the background geostrophic flow associated with the Bermuda high, resulting in a maximum low-level mean summertime flow over the Great Plains region. Maximum geostrophic winds in the NAM are found during late afternoon, providing a large background wind on which frictional decoupling can act. The nighttime LLJ maximum is the result of an inertial oscillation of the unbalanced components that arise fundamentally from frictional decoupling. Diurnal heating of the sloping terrain forces a cycle in the geostrophic wind that is out of phase with the wind maximum.
ISSN:0022-4928
1520-0469
DOI:10.1175/2010jas3368.1