Density currents as a desert dust mobilization mechanism

The formation and propagation of density currents are well studied processes in fluid dynamics with many applications in other science fields. In the atmosphere, density currents are usually meso-β/γ phenomena and are often associated with storm downdrafts. These storms are responsible for the forma...

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Main Authors: S. Solomos, G. Kallos, E. Mavromatidis, J. Kushta
Format: Article
Language:English
Published: Copernicus Publications 2012-11-01
Series:Atmospheric Chemistry and Physics
Online Access:http://www.atmos-chem-phys.net/12/11199/2012/acp-12-11199-2012.pdf
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spelling doaj-f6c0ddf77c644bf0bbb9eaace553eba92020-11-24T23:41:09ZengCopernicus PublicationsAtmospheric Chemistry and Physics1680-73161680-73242012-11-011222111991121110.5194/acp-12-11199-2012Density currents as a desert dust mobilization mechanismS. SolomosG. KallosE. MavromatidisJ. KushtaThe formation and propagation of density currents are well studied processes in fluid dynamics with many applications in other science fields. In the atmosphere, density currents are usually meso-β/γ phenomena and are often associated with storm downdrafts. These storms are responsible for the formation of severe dust episodes (haboobs) over desert areas. In the present study, the formation of a convective cool pool and the associated dust mobilization are examined for a representative event over the western part of Sahara desert. The physical processes involved in the mobilization of dust are described with the use of the integrated atmospheric-air quality RAMS/ICLAMS model. Dust is effectively produced due to the development of near surface vortices and increased turbulent mixing along the frontal line. Increased dust emissions and recirculation of the elevated particles inside the head of the density current result in the formation of a moving "dust wall". Transport of the dust particles in higher layers – outside of the density current – occurs mainly in three ways: (1) Uplifting of preexisting dust over the frontal line with the aid of the strong updraft (2) Entrainment at the upper part of the density current head due to turbulent mixing (3) Vertical mixing after the dilution of the system. The role of the dust in the associated convective cloud system was found to be limited. Proper representation of convective processes and dust mobilization requires the use of high resolution (cloud resolving) model configuration and online parameterization of dust production. Haboob-type dust storms are effective dust sources and should be treated accordingly in dust modeling applications.http://www.atmos-chem-phys.net/12/11199/2012/acp-12-11199-2012.pdf
collection DOAJ
language English
format Article
sources DOAJ
author S. Solomos
G. Kallos
E. Mavromatidis
J. Kushta
spellingShingle S. Solomos
G. Kallos
E. Mavromatidis
J. Kushta
Density currents as a desert dust mobilization mechanism
Atmospheric Chemistry and Physics
author_facet S. Solomos
G. Kallos
E. Mavromatidis
J. Kushta
author_sort S. Solomos
title Density currents as a desert dust mobilization mechanism
title_short Density currents as a desert dust mobilization mechanism
title_full Density currents as a desert dust mobilization mechanism
title_fullStr Density currents as a desert dust mobilization mechanism
title_full_unstemmed Density currents as a desert dust mobilization mechanism
title_sort density currents as a desert dust mobilization mechanism
publisher Copernicus Publications
series Atmospheric Chemistry and Physics
issn 1680-7316
1680-7324
publishDate 2012-11-01
description The formation and propagation of density currents are well studied processes in fluid dynamics with many applications in other science fields. In the atmosphere, density currents are usually meso-β/γ phenomena and are often associated with storm downdrafts. These storms are responsible for the formation of severe dust episodes (haboobs) over desert areas. In the present study, the formation of a convective cool pool and the associated dust mobilization are examined for a representative event over the western part of Sahara desert. The physical processes involved in the mobilization of dust are described with the use of the integrated atmospheric-air quality RAMS/ICLAMS model. Dust is effectively produced due to the development of near surface vortices and increased turbulent mixing along the frontal line. Increased dust emissions and recirculation of the elevated particles inside the head of the density current result in the formation of a moving "dust wall". Transport of the dust particles in higher layers – outside of the density current – occurs mainly in three ways: (1) Uplifting of preexisting dust over the frontal line with the aid of the strong updraft (2) Entrainment at the upper part of the density current head due to turbulent mixing (3) Vertical mixing after the dilution of the system. The role of the dust in the associated convective cloud system was found to be limited. Proper representation of convective processes and dust mobilization requires the use of high resolution (cloud resolving) model configuration and online parameterization of dust production. Haboob-type dust storms are effective dust sources and should be treated accordingly in dust modeling applications.
url http://www.atmos-chem-phys.net/12/11199/2012/acp-12-11199-2012.pdf
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