Editorial Type:
Article
Article Type:
Research Article

Nocturnal Low-Level Jet in a Mountain Basin Complex. Part I: Evolution and Effects on Local Flows

Robert M. Banta NOAA/Environmental Technology Laboratory, Boulder, Colorado

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Lisa S. Darby NOAA/Environmental Technology Laboratory, Boulder, Colorado

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Jerome D. Fast Pacific Northwest National Laboratory, Richland, Washington

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James O. Pinto National Center for Atmospheric Research, Boulder, Colorado

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C. David Whiteman Pacific Northwest National Laboratory, Richland, Washington

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William J. Shaw Pacific Northwest National Laboratory, Richland, Washington

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Brad W. Orr NOAA/Environmental Technology Laboratory, Boulder, Colorado

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Print Publication:
01 Oct 2004
DOI:
https://doi.org/10.1175/JAM2142.1
Page(s):
1348–1365
Restricted access

Abstract

A Doppler lidar deployed to the center of the Great Salt Lake (GSL) basin during the Vertical Transport and Mixing (VTMX) field campaign in October 2000 found a diurnal cycle of the along-basin winds with northerly up-basin flow during the day and a southerly down-basin low-level jet at night. The emphasis of VTMX was on stable atmospheric processes in the cold-air pool that formed in the basin at night. During the night the jet was fully formed as it entered the GSL basin from the south. Thus, it was a feature of the complex string of basins draining toward the Great Salt Lake, which included at least the Utah Lake basin to the south. The timing of the evening reversal to down-basin flow was sensitive to the larger-scale north–south pressure gradient imposed on the basin complex. On nights when the pressure gradient was not too strong, local drainage flow (slope flows and canyon outflow) was well developed along the Wasatch Range to the east and coexisted with the basin jet. The coexistence of these two types of flow generated localized regions of convergence and divergence, in which regions of vertical motion and transport were focused. Mesoscale numerical simulations captured these features and indicated that updrafts on the order of 5 cm s−1 could persist in these localized convergence zones, contributing to vertical displacement of air masses within the basin cold pool.

Corresponding author address: Robert M. Banta, NOAA (ET2), 325 Broadway, Boulder, CO 80305. robert.banta@noaa.gov

Abstract

A Doppler lidar deployed to the center of the Great Salt Lake (GSL) basin during the Vertical Transport and Mixing (VTMX) field campaign in October 2000 found a diurnal cycle of the along-basin winds with northerly up-basin flow during the day and a southerly down-basin low-level jet at night. The emphasis of VTMX was on stable atmospheric processes in the cold-air pool that formed in the basin at night. During the night the jet was fully formed as it entered the GSL basin from the south. Thus, it was a feature of the complex string of basins draining toward the Great Salt Lake, which included at least the Utah Lake basin to the south. The timing of the evening reversal to down-basin flow was sensitive to the larger-scale north–south pressure gradient imposed on the basin complex. On nights when the pressure gradient was not too strong, local drainage flow (slope flows and canyon outflow) was well developed along the Wasatch Range to the east and coexisted with the basin jet. The coexistence of these two types of flow generated localized regions of convergence and divergence, in which regions of vertical motion and transport were focused. Mesoscale numerical simulations captured these features and indicated that updrafts on the order of 5 cm s−1 could persist in these localized convergence zones, contributing to vertical displacement of air masses within the basin cold pool.

Corresponding author address: Robert M. Banta, NOAA (ET2), 325 Broadway, Boulder, CO 80305. robert.banta@noaa.gov

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Journal of Applied Meteorology and Climatology

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