Investigating the liquid water path over the tropical Atlantic with synergistic airborne measurements

Investigating the liquid water path over the tropical Atlantic with synergistic airborne measurements

Liquid water path (LWP) is an important quantity to characterize clouds. Passive microwave satellite sensors provide the most direct estimate on a global scale but suffer from high uncertainties due to large footprints and the superposition of cloud and precipitation signals. Here, we use high spati...

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Veröffentlicht in:Atmospheric measurement techniques 2019-06, Vol.12 (6), p.3237-3254
Hauptverfasser: Jacob, Marek, Ament, Felix, Gutleben, Manuel, Konow, Heike, Mech, Mario, Wirth, Martin, Crewell, Susanne
Format: Artikel
Sprache:eng
Schlagworte:
Airborne remote sensing
Airborne sensing
Aircraft
Artificial neural networks
Atmospheric water
Backscatter
Backscattering
Cloud cover
Clouds
Clouds (Meteorology)
Computer simulation
Confidence
Distribution
Drizzle
Dropsondes
Dry season
Error analysis
High altitude
Lidar
Lidar measurements
Measurement
Meteorological satellites
Microwave radiometers
Microwave scattering
Neural networks
Optical radar
Organizations
Precipitation
Radar
Radiometers
Rain
Rain water
Rainwater
Rainy season
Remote sensing
Research aircraft
Retrieval
Seasons
Sensors
Spatial discrimination
Spatial resolution
Statistical methods
Superposition (mathematics)
Theoretical analysis
Tropical climate
Uncertainty
Water
Water vapor
Water vapour
Wet season
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Beschreibung
Zusammenfassung:Liquid water path (LWP) is an important quantity to characterize clouds. Passive microwave satellite sensors provide the most direct estimate on a global scale but suffer from high uncertainties due to large footprints and the superposition of cloud and precipitation signals. Here, we use high spatial resolution airborne microwave radiometer (MWR) measurements together with cloud radar and lidar observations to better understand the LWP of warm clouds over the tropical North Atlantic. The nadir measurements were taken by the German High Altitude and LOng range research aircraft (HALO) in December 2013 (dry season) and August 2016 (wet season) during two Next-generation Advanced Remote sensing for VALidation (NARVAL) campaigns.
ISSN:1867-8548
1867-1381
1867-8548
DOI:10.5194/amt-12-3237-2019