Airborne Lidar Observations of Water Vapor Variability in Tropical Shallow Convective Environment

An airborne downward-pointing water vapor lidar provides two-dimensional, simultaneous curtains of atmospheric backscatter and humidity along the flight track with high accuracy and spatial resolution. In order to improve the knowledge on the coupling between clouds, circulation and climate in the t...

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Bibliographic Details
Main Authors:	Kiemle, Christoph, Groß, Silke Martha, Wirth, Martin, Bugliaro Goggia, Luca
Other Authors:	Pincus, Robert, Winkler, David, Bony, Sandrine, Stevens, Bjorn
Format:	Book Part
Language:	unknown
Published:	Spinger 2018
Subjects:	Lidar narval
Online Access:	https://elib.dlr.de/120798/ https://link.springer.com/book/10.1007/978-3-319-77273-8

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record_format	openpolar
spelling	ftdlr:oai:elib.dlr.de:120798 2024-04-21T08:13:08+00:00 Airborne Lidar Observations of Water Vapor Variability in Tropical Shallow Convective Environment Kiemle, Christoph Groß, Silke Martha Wirth, Martin Bugliaro Goggia, Luca Pincus, Robert Winkler, David Bony, Sandrine Stevens, Bjorn 2018 https://elib.dlr.de/120798/ https://link.springer.com/book/10.1007/978-3-319-77273-8 unknown Spinger Kiemle, Christoph und Groß, Silke Martha und Wirth, Martin und Bugliaro Goggia, Luca (2018) Airborne Lidar Observations of Water Vapor Variability in Tropical Shallow Convective Environment. In: Shallow Clouds, Water Vapor, Circulation, and Climate Sensitivity Space Scienc Series of ISSI, 65. Spinger. Seiten 253-271. doi:10.1007/978-3-319-77273-8_12 <https://doi.org/10.1007/978-3-319-77273-8_12>. ISBN 978-3-319-77272-1. Lidar Beitrag in einem Lehr- oder Fachbuch PeerReviewed 2018 ftdlr https://doi.org/10.1007/978-3-319-77273-8_12 2024-03-25T15:00:30Z An airborne downward-pointing water vapor lidar provides two-dimensional, simultaneous curtains of atmospheric backscatter and humidity along the flight track with high accuracy and spatial resolution. In order to improve the knowledge on the coupling between clouds, circulation and climate in the trade wind region, the DLR (Deutsches Zentrum für Luft- und Raumfahrt) water vapor lidar was operated on board the German research aircraft HALO during the NARVAL (Next Generation Aircraft Remote Sensing for Validation Studies) field experiment in December 2013. Out of the wealth of about 30 flight hours or 25,000 km of data over the Tropical Atlantic Ocean east of Barbados, three 2-h-long, representative segments from different flights were selected. Analyses of Meteosat Second Generation images and dropsondes complement this case study. All observations indicate a high heterogeneity of the humidity in the lowest 4 km of the tropical troposphere, as well as of the depth of the cloud (1–2 km thick) and sub-cloud layer (1 km thick). At the winter trade inversion with its strong humidity jump of up to 9 g/kg in water vapor mixing ratio, the mixing ratio variance can attain 9 (g/kg)2, while below it typically ranges between 1 and 3 (g/kg)2. Layer depths and partial water vapor columns within the layers vary by up to a factor of 2. This affects the total tropospheric water vapor column, amounting on average to 28 kg/m2, by up to 10 kg/m2 or 36%. The dominant scale of the variability is given by the extent of regions with higher-than-average humidity and lies between 300 and 600 km. The variability mainly stems from the alternation between dry regions and moisture lifted by convection. Occasionally, up to 100-km large dry regions are observed. In between, convection pushes the trade inversion upward, sharpening the vertical moisture gradient that is colocated with the trade inversion. In most of the water vapor profiles, this gradient is stronger than the one located at the top of the sub-cloud layer. Lidar observations in ... Book Part narval narval German Aerospace Center: elib - DLR electronic library 253 271
institution	Open Polar
collection	German Aerospace Center: elib - DLR electronic library
op_collection_id	ftdlr
language	unknown
topic	Lidar
spellingShingle	Lidar Kiemle, Christoph Groß, Silke Martha Wirth, Martin Bugliaro Goggia, Luca Airborne Lidar Observations of Water Vapor Variability in Tropical Shallow Convective Environment
topic_facet	Lidar
description	An airborne downward-pointing water vapor lidar provides two-dimensional, simultaneous curtains of atmospheric backscatter and humidity along the flight track with high accuracy and spatial resolution. In order to improve the knowledge on the coupling between clouds, circulation and climate in the trade wind region, the DLR (Deutsches Zentrum für Luft- und Raumfahrt) water vapor lidar was operated on board the German research aircraft HALO during the NARVAL (Next Generation Aircraft Remote Sensing for Validation Studies) field experiment in December 2013. Out of the wealth of about 30 flight hours or 25,000 km of data over the Tropical Atlantic Ocean east of Barbados, three 2-h-long, representative segments from different flights were selected. Analyses of Meteosat Second Generation images and dropsondes complement this case study. All observations indicate a high heterogeneity of the humidity in the lowest 4 km of the tropical troposphere, as well as of the depth of the cloud (1–2 km thick) and sub-cloud layer (1 km thick). At the winter trade inversion with its strong humidity jump of up to 9 g/kg in water vapor mixing ratio, the mixing ratio variance can attain 9 (g/kg)2, while below it typically ranges between 1 and 3 (g/kg)2. Layer depths and partial water vapor columns within the layers vary by up to a factor of 2. This affects the total tropospheric water vapor column, amounting on average to 28 kg/m2, by up to 10 kg/m2 or 36%. The dominant scale of the variability is given by the extent of regions with higher-than-average humidity and lies between 300 and 600 km. The variability mainly stems from the alternation between dry regions and moisture lifted by convection. Occasionally, up to 100-km large dry regions are observed. In between, convection pushes the trade inversion upward, sharpening the vertical moisture gradient that is colocated with the trade inversion. In most of the water vapor profiles, this gradient is stronger than the one located at the top of the sub-cloud layer. Lidar observations in ...
author2	Pincus, Robert Winkler, David Bony, Sandrine Stevens, Bjorn
format	Book Part
author	Kiemle, Christoph Groß, Silke Martha Wirth, Martin Bugliaro Goggia, Luca
author_facet	Kiemle, Christoph Groß, Silke Martha Wirth, Martin Bugliaro Goggia, Luca
author_sort	Kiemle, Christoph
title	Airborne Lidar Observations of Water Vapor Variability in Tropical Shallow Convective Environment
title_short	Airborne Lidar Observations of Water Vapor Variability in Tropical Shallow Convective Environment
title_full	Airborne Lidar Observations of Water Vapor Variability in Tropical Shallow Convective Environment
title_fullStr	Airborne Lidar Observations of Water Vapor Variability in Tropical Shallow Convective Environment
title_full_unstemmed	Airborne Lidar Observations of Water Vapor Variability in Tropical Shallow Convective Environment
title_sort	airborne lidar observations of water vapor variability in tropical shallow convective environment
publisher	Spinger
publishDate	2018
url	https://elib.dlr.de/120798/ https://link.springer.com/book/10.1007/978-3-319-77273-8
genre	narval narval
genre_facet	narval narval
op_relation	Kiemle, Christoph und Groß, Silke Martha und Wirth, Martin und Bugliaro Goggia, Luca (2018) Airborne Lidar Observations of Water Vapor Variability in Tropical Shallow Convective Environment. In: Shallow Clouds, Water Vapor, Circulation, and Climate Sensitivity Space Scienc Series of ISSI, 65. Spinger. Seiten 253-271. doi:10.1007/978-3-319-77273-8_12 <https://doi.org/10.1007/978-3-319-77273-8_12>. ISBN 978-3-319-77272-1.
op_doi	https://doi.org/10.1007/978-3-319-77273-8_12
container_start_page	253
op_container_end_page	271
_version_	1796933681013587968

Airborne Lidar Observations of Water Vapor Variability in Tropical Shallow Convective Environment

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