Unmanned Aerial Systems for Investigating the Polar Atmospheric Boundary Layer—Technical Challenges and Examples of Applications

Unmanned aerial systems (UAS) fill a gap in high-resolution observations of meteorological parameters on small scales in the atmospheric boundary layer (ABL). Especially in the remote polar areas, there is a strong need for such detailed observations with different research foci. In this study, thre...

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Main Authors: Lampert, Astrid, Altstädter, Barbara, Bärfuss, Konrad, Bretschneider, Lutz, Sandgaard, Jesper, Michaelis, Janosch, Lobitz, Lennart, Asmussen, Magnus, Damm, Ellen, Käthner, Ralf, Krüger, Thomas, Lüpkes, Christof, Nowak, Stefan, Peuker, Alexander, Rausch, Thomas, Reiser, Fabian, Scholtz, Andreas, Zakharov, Denis Sotomayor, Gaus, Dominik, Bansmer, Stephan, Wehner, Birgit, Pätzold, Falk
Format: Article in Journal/Newspaper
Language:English
Published: Basel, Switzerland : MDPI AG 2020
Subjects:
550
Online Access:https://oa.tib.eu/renate/handle/123456789/6884
https://doi.org/10.34657/5931
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spelling ftleibnizopen:oai:oai.leibnizopen.de:WjA974cBdbrxVwz6PceH 2023-06-11T04:06:59+02:00 Unmanned Aerial Systems for Investigating the Polar Atmospheric Boundary Layer—Technical Challenges and Examples of Applications Lampert, Astrid Altstädter, Barbara Bärfuss, Konrad Bretschneider, Lutz Sandgaard, Jesper Michaelis, Janosch Lobitz, Lennart Asmussen, Magnus Damm, Ellen Käthner, Ralf Krüger, Thomas Lüpkes, Christof Nowak, Stefan Peuker, Alexander Rausch, Thomas Reiser, Fabian Scholtz, Andreas Zakharov, Denis Sotomayor Gaus, Dominik Bansmer, Stephan Wehner, Birgit Pätzold, Falk 2020 application/pdf https://oa.tib.eu/renate/handle/123456789/6884 https://doi.org/10.34657/5931 eng eng Basel, Switzerland : MDPI AG CC BY 4.0 Unported https://creativecommons.org/licenses/by/4.0/ Atmosphere 11 (2020), Nr. 4 Atmospheric boundary layer Meteorological sensors Polar atmosphere Unmanned aerial systems 550 article Text 2020 ftleibnizopen https://doi.org/10.34657/5931 2023-05-07T23:09:25Z Unmanned aerial systems (UAS) fill a gap in high-resolution observations of meteorological parameters on small scales in the atmospheric boundary layer (ABL). Especially in the remote polar areas, there is a strong need for such detailed observations with different research foci. In this study, three systems are presented which have been adapted to the particular needs for operating in harsh polar environments: The fixed-wing aircraft M2AV with a mass of 6 kg, the quadrocopter ALICE with a mass of 19 kg, and the fixed-wing aircraft ALADINA with a mass of almost 25 kg. For all three systems, their particular modifications for polar operations are documented, in particular the insulation and heating requirements for low temperatures. Each system has completed meteorological observations under challenging conditions, including take-offand landing on the ice surface, low temperatures (down to-28 °C), icing, and, for the quadrocopter, under the impact of the rotor downwash. The influence on the measured parameters is addressed here in the form of numerical simulations and spectral data analysis. Furthermore, results from several case studies are discussed: With the M2AV, low-level flights above leads in Antarctic sea ice were performed to study the impact of areas of open water within ice surfaces on the ABL, and a comparison with simulations was performed. ALICE was used to study the small-scale structure and short-term variability of the ABL during a cruise of RV Polarstern to the 79° N glacier in Greenland. With ALADINA, aerosol measurements of different size classes were performed in Ny-Alesund, Svalbard, in highly complex terrain. In particular, very small, freshly formed particles are difficult to monitor and require the active control of temperature inside the instruments. The main aim of the article is to demonstrate the potential of UAS for ABL studies in polar environments, and to provide practical advice for future research activities with similar systems. © 2020 by the authors. publishedVersion Article in Journal/Newspaper Antarc* Antarctic glacier glacier Greenland Sea ice Svalbard LeibnizOpen (The Leibniz Association) Antarctic Greenland Svalbard
institution Open Polar
collection LeibnizOpen (The Leibniz Association)
op_collection_id ftleibnizopen
language English
topic Atmospheric boundary layer
Meteorological sensors
Polar atmosphere
Unmanned aerial systems
550
spellingShingle Atmospheric boundary layer
Meteorological sensors
Polar atmosphere
Unmanned aerial systems
550
Lampert, Astrid
Altstädter, Barbara
Bärfuss, Konrad
Bretschneider, Lutz
Sandgaard, Jesper
Michaelis, Janosch
Lobitz, Lennart
Asmussen, Magnus
Damm, Ellen
Käthner, Ralf
Krüger, Thomas
Lüpkes, Christof
Nowak, Stefan
Peuker, Alexander
Rausch, Thomas
Reiser, Fabian
Scholtz, Andreas
Zakharov, Denis Sotomayor
Gaus, Dominik
Bansmer, Stephan
Wehner, Birgit
Pätzold, Falk
Unmanned Aerial Systems for Investigating the Polar Atmospheric Boundary Layer—Technical Challenges and Examples of Applications
topic_facet Atmospheric boundary layer
Meteorological sensors
Polar atmosphere
Unmanned aerial systems
550
description Unmanned aerial systems (UAS) fill a gap in high-resolution observations of meteorological parameters on small scales in the atmospheric boundary layer (ABL). Especially in the remote polar areas, there is a strong need for such detailed observations with different research foci. In this study, three systems are presented which have been adapted to the particular needs for operating in harsh polar environments: The fixed-wing aircraft M2AV with a mass of 6 kg, the quadrocopter ALICE with a mass of 19 kg, and the fixed-wing aircraft ALADINA with a mass of almost 25 kg. For all three systems, their particular modifications for polar operations are documented, in particular the insulation and heating requirements for low temperatures. Each system has completed meteorological observations under challenging conditions, including take-offand landing on the ice surface, low temperatures (down to-28 °C), icing, and, for the quadrocopter, under the impact of the rotor downwash. The influence on the measured parameters is addressed here in the form of numerical simulations and spectral data analysis. Furthermore, results from several case studies are discussed: With the M2AV, low-level flights above leads in Antarctic sea ice were performed to study the impact of areas of open water within ice surfaces on the ABL, and a comparison with simulations was performed. ALICE was used to study the small-scale structure and short-term variability of the ABL during a cruise of RV Polarstern to the 79° N glacier in Greenland. With ALADINA, aerosol measurements of different size classes were performed in Ny-Alesund, Svalbard, in highly complex terrain. In particular, very small, freshly formed particles are difficult to monitor and require the active control of temperature inside the instruments. The main aim of the article is to demonstrate the potential of UAS for ABL studies in polar environments, and to provide practical advice for future research activities with similar systems. © 2020 by the authors. publishedVersion
format Article in Journal/Newspaper
author Lampert, Astrid
Altstädter, Barbara
Bärfuss, Konrad
Bretschneider, Lutz
Sandgaard, Jesper
Michaelis, Janosch
Lobitz, Lennart
Asmussen, Magnus
Damm, Ellen
Käthner, Ralf
Krüger, Thomas
Lüpkes, Christof
Nowak, Stefan
Peuker, Alexander
Rausch, Thomas
Reiser, Fabian
Scholtz, Andreas
Zakharov, Denis Sotomayor
Gaus, Dominik
Bansmer, Stephan
Wehner, Birgit
Pätzold, Falk
author_facet Lampert, Astrid
Altstädter, Barbara
Bärfuss, Konrad
Bretschneider, Lutz
Sandgaard, Jesper
Michaelis, Janosch
Lobitz, Lennart
Asmussen, Magnus
Damm, Ellen
Käthner, Ralf
Krüger, Thomas
Lüpkes, Christof
Nowak, Stefan
Peuker, Alexander
Rausch, Thomas
Reiser, Fabian
Scholtz, Andreas
Zakharov, Denis Sotomayor
Gaus, Dominik
Bansmer, Stephan
Wehner, Birgit
Pätzold, Falk
author_sort Lampert, Astrid
title Unmanned Aerial Systems for Investigating the Polar Atmospheric Boundary Layer—Technical Challenges and Examples of Applications
title_short Unmanned Aerial Systems for Investigating the Polar Atmospheric Boundary Layer—Technical Challenges and Examples of Applications
title_full Unmanned Aerial Systems for Investigating the Polar Atmospheric Boundary Layer—Technical Challenges and Examples of Applications
title_fullStr Unmanned Aerial Systems for Investigating the Polar Atmospheric Boundary Layer—Technical Challenges and Examples of Applications
title_full_unstemmed Unmanned Aerial Systems for Investigating the Polar Atmospheric Boundary Layer—Technical Challenges and Examples of Applications
title_sort unmanned aerial systems for investigating the polar atmospheric boundary layer—technical challenges and examples of applications
publisher Basel, Switzerland : MDPI AG
publishDate 2020
url https://oa.tib.eu/renate/handle/123456789/6884
https://doi.org/10.34657/5931
geographic Antarctic
Greenland
Svalbard
geographic_facet Antarctic
Greenland
Svalbard
genre Antarc*
Antarctic
glacier
glacier
Greenland
Sea ice
Svalbard
genre_facet Antarc*
Antarctic
glacier
glacier
Greenland
Sea ice
Svalbard
op_source Atmosphere 11 (2020), Nr. 4
op_rights CC BY 4.0 Unported
https://creativecommons.org/licenses/by/4.0/
op_doi https://doi.org/10.34657/5931
_version_ 1768379341926825984