Tracking the Saharan Air Layer with shipborne lidar across the tropical Atlantic

Saharan dust was observed with shipborne lidar from 60° to 20°W along 14.5°N during a 1-month transatlantic cruise of the research vessel Meteor. About 4500 km off the coast of Africa, mean extinction and backscatter-related Ångström exponent of 0.1, wavelength-independent extinction-to-backscatter...

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Main Authors: Kanitz, T., Engelmann, R., Heinold, B., Baars, H., Skupin, A., Ansmann, A.
Format: Article in Journal/Newspaper
Language:English
Published: Hoboken, NJ : Wiley 2014
Subjects:
550
Online Access:https://doi.org/10.34657/1377
https://oa.tib.eu/renate/handle/123456789/835
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spelling ftleibnizopen:oai:oai.leibnizopen.de:kSePVYsBBwLIz6xGsAph 2023-11-12T03:59:48+01:00 Tracking the Saharan Air Layer with shipborne lidar across the tropical Atlantic Kanitz, T. Engelmann, R. Heinold, B. Baars, H. Skupin, A. Ansmann, A. 2014 application/pdf https://doi.org/10.34657/1377 https://oa.tib.eu/renate/handle/123456789/835 eng eng Hoboken, NJ : Wiley CC BY-NC-ND 3.0 Unported https://creativecommons.org/licenses/by-nc-nd/3.0/ Geophysical research letters, Volume 41, Issue 3, Page 1044-1050 Aerosol optical thickness Atmospheric residence time Backscatter coefficients Dust concentrations Extinction-to-backscatter ratio Lidar measurements Linear depolarization ratios Saharan dust 550 article Text 2014 ftleibnizopen https://doi.org/10.34657/1377 2023-10-22T23:18:52Z Saharan dust was observed with shipborne lidar from 60° to 20°W along 14.5°N during a 1-month transatlantic cruise of the research vessel Meteor. About 4500 km off the coast of Africa, mean extinction and backscatter-related Ångström exponent of 0.1, wavelength-independent extinction-to-backscatter ratios (lidar ratios) of around 45 sr, and particle linear depolarization ratio of 20% were found for aged dust (transport time >10 days). In contrast, dust with a shorter atmospheric residence time of 2–3 days showed Ångström exponents of −0.5 (backscatter coefficient) and 0.1 (extinction coefficient), mean lidar ratios of 64 and 50 sr, and particle linear depolarization ratios of 22 and 26% at 355 and 532 nm wavelength, respectively. Traces of fire smoke were also detected in the observed dust layers. The lidar observations were complemented by Aerosol Robotic Network handheld Sun photometer measurements, which revealed a mean total atmospheric column aerosol optical thickness of 0.05 for pure marine conditions (in the absence of lofted aerosol layers) and roughly 0.9 during a strong Saharan dust outbreak. The achieved data set was compared with first Consortium for Small Scale Modeling-Multi-Scale Chemistry Aerosol Transport simulations. The simulated vertical aerosol distribution showed good agreement with the lidar observations. publishedVersion Article in Journal/Newspaper Aerosol Robotic Network Unknown
institution Open Polar
collection Unknown
op_collection_id ftleibnizopen
language English
topic Aerosol optical thickness
Atmospheric residence time
Backscatter coefficients
Dust concentrations
Extinction-to-backscatter ratio
Lidar measurements
Linear depolarization ratios
Saharan dust
550
spellingShingle Aerosol optical thickness
Atmospheric residence time
Backscatter coefficients
Dust concentrations
Extinction-to-backscatter ratio
Lidar measurements
Linear depolarization ratios
Saharan dust
550
Kanitz, T.
Engelmann, R.
Heinold, B.
Baars, H.
Skupin, A.
Ansmann, A.
Tracking the Saharan Air Layer with shipborne lidar across the tropical Atlantic
topic_facet Aerosol optical thickness
Atmospheric residence time
Backscatter coefficients
Dust concentrations
Extinction-to-backscatter ratio
Lidar measurements
Linear depolarization ratios
Saharan dust
550
description Saharan dust was observed with shipborne lidar from 60° to 20°W along 14.5°N during a 1-month transatlantic cruise of the research vessel Meteor. About 4500 km off the coast of Africa, mean extinction and backscatter-related Ångström exponent of 0.1, wavelength-independent extinction-to-backscatter ratios (lidar ratios) of around 45 sr, and particle linear depolarization ratio of 20% were found for aged dust (transport time >10 days). In contrast, dust with a shorter atmospheric residence time of 2–3 days showed Ångström exponents of −0.5 (backscatter coefficient) and 0.1 (extinction coefficient), mean lidar ratios of 64 and 50 sr, and particle linear depolarization ratios of 22 and 26% at 355 and 532 nm wavelength, respectively. Traces of fire smoke were also detected in the observed dust layers. The lidar observations were complemented by Aerosol Robotic Network handheld Sun photometer measurements, which revealed a mean total atmospheric column aerosol optical thickness of 0.05 for pure marine conditions (in the absence of lofted aerosol layers) and roughly 0.9 during a strong Saharan dust outbreak. The achieved data set was compared with first Consortium for Small Scale Modeling-Multi-Scale Chemistry Aerosol Transport simulations. The simulated vertical aerosol distribution showed good agreement with the lidar observations. publishedVersion
format Article in Journal/Newspaper
author Kanitz, T.
Engelmann, R.
Heinold, B.
Baars, H.
Skupin, A.
Ansmann, A.
author_facet Kanitz, T.
Engelmann, R.
Heinold, B.
Baars, H.
Skupin, A.
Ansmann, A.
author_sort Kanitz, T.
title Tracking the Saharan Air Layer with shipborne lidar across the tropical Atlantic
title_short Tracking the Saharan Air Layer with shipborne lidar across the tropical Atlantic
title_full Tracking the Saharan Air Layer with shipborne lidar across the tropical Atlantic
title_fullStr Tracking the Saharan Air Layer with shipborne lidar across the tropical Atlantic
title_full_unstemmed Tracking the Saharan Air Layer with shipborne lidar across the tropical Atlantic
title_sort tracking the saharan air layer with shipborne lidar across the tropical atlantic
publisher Hoboken, NJ : Wiley
publishDate 2014
url https://doi.org/10.34657/1377
https://oa.tib.eu/renate/handle/123456789/835
genre Aerosol Robotic Network
genre_facet Aerosol Robotic Network
op_source Geophysical research letters, Volume 41, Issue 3, Page 1044-1050
op_rights CC BY-NC-ND 3.0 Unported
https://creativecommons.org/licenses/by-nc-nd/3.0/
op_doi https://doi.org/10.34657/1377
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