The Extreme North African Haboob in October 2008: High‐Resolution Simulation of Organized Moist Convection in the Lee of the Atlas, Dust Recirculation and Poleward Transport

This study investigates the mesoscale dynamics involved in the 8–11 October 2008 unseasonably strong African dust episode, during which dust was transported to the Iberian Peninsula (IP). We employ observational datasets and a high‐resolution Weather Research and Forecasting model coupled with Chemi...

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Published in:Journal of geophysical research. Atmospheres 2022-10, Vol.127 (20), p.n/a
Main Authors: Dhital, S., Kaplan, M. L., Orza, J. A. G., Fiedler, S.
Format: Article
Language:English
Subjects:
Atmospheric particulates
Cold
Confluence
Convection
Dust
Dust plumes
dust storm
dust‐emission and long‐range transport
Foothills
Geophysics
Mesoscale convective systems
mesoscale dynamics
Mesoscale phenomena
Moist convection
Mountains
Outflow
Resolution
Slopes
Weather forecasting
WRF‐Chem
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container_title Journal of geophysical research. Atmospheres
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Kaplan, M. L.
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description This study investigates the mesoscale dynamics involved in the 8–11 October 2008 unseasonably strong African dust episode, during which dust was transported to the Iberian Peninsula (IP). We employ observational datasets and a high‐resolution Weather Research and Forecasting model coupled with Chemistry simulations. The analysis shows that during 0900–1200 UTC 9 October, a mesoscale convective system developed over the Atlas Mountains and resulted in a southwestward propagating convective cold pool outflow on the southern foothills of the Anti‐Atlas, which lifted dust from the source region. Between 1200 and 1800 UTC 9 October, new moist convection was enhanced over the Atlas Mountains due to intensifying confluence among a heat low, moist southwesterly Atlantic sea‐breeze front, and northeasterly flow associated with the convective cold pool near western Algeria. This new moist convection intensified the strength of the convective cold pool outflow and haboob, both of which continued propagating southwestward. At 1200 UTC 10 October, the low‐pressure system migrated poleward on the southern slopes of the Anti‐Atlas Mountains in association with a mountain‐plains solenoidal circulation due to the daytime differential heating between the southern slopes of the Anti‐Atlas and nearby atmosphere. The deepening low‐pressure and strengthening Atlantic sea‐breeze redirected an equatorward advancing dust plume into the poleward direction. The dust plume ultimately crossed the Saharan Atlas Mountains on 11 October and finally impacted the IP. Key Points WRF‐Chem simulation of an unseasonably strong haboob on the southern slopes of the Atlas Mountains The equatorward‐advancing dust plume was recirculated in the poleward direction by an Atlantic sea‐breeze front The Atlantic sea‐breeze front and an intensified upper‐level cutoff vortex are instrumental for dust transport over the Iberian Peninsula
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source Wiley; Alma/SFX Local Collection
subjects Atmospheric particulates
Cold
Confluence
Convection
Dust
Dust plumes
dust storm
dust‐emission and long‐range transport
Foothills
Geophysics
Mesoscale convective systems
mesoscale dynamics
Mesoscale phenomena
Moist convection
Mountains
Outflow
Resolution
Slopes
Weather forecasting
WRF‐Chem
title The Extreme North African Haboob in October 2008: High‐Resolution Simulation of Organized Moist Convection in the Lee of the Atlas, Dust Recirculation and Poleward Transport
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