PMC-Turbo: a balloon-borne Mission to image gravity waves and turbulence in polar mesospheric clouds

PMC-Turbo is a balloon-borne experiment that will fly at an altitude between 35 and 40 km. It is designed to record gravity wave events in polar mesospheric clouds with high spatial and temporal resolution as they unfold across a large field of the sky. The project is motivated by the serendipitous...

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Main Authors: Kaifler, Bernd, Fritts, David C., Miller, Amber, Limon, Michele, Jones, Glenn, Kjellstrand, Bjorn, Williams, Bifford P., Wang, Ling, Reimuller, Jason, Hanany, Shaul, Geach, Christopher, Taylor, M.
Format: Conference Object
Language:English
Published: 2017
Subjects:
Lidar
Arctic
Antarc*
Antarctica
Online Access:https://elib.dlr.de/114378/
https://elib.dlr.de/114378/1/1709_BK_PMCTurbo_LPMR.pdf
https://www.iap-kborn.de/fileadmin/user_upload/Current_issue/Workshops/LPMR2017/data/abstracts/abstract_73.html
id ftdlr:oai:elib.dlr.de:114378
record_format openpolar
institution Open Polar
collection German Aerospace Center: elib - DLR electronic library
op_collection_id ftdlr
language English
topic Lidar
spellingShingle Lidar
Kaifler, Bernd
Fritts, David C.
Miller, Amber
Limon, Michele
Jones, Glenn
Kjellstrand, Bjorn
Williams, Bifford P.
Wang, Ling
Reimuller, Jason
Hanany, Shaul
Geach, Christopher
Taylor, M.
PMC-Turbo: a balloon-borne Mission to image gravity waves and turbulence in polar mesospheric clouds
topic_facet Lidar
description PMC-Turbo is a balloon-borne experiment that will fly at an altitude between 35 and 40 km. It is designed to record gravity wave events in polar mesospheric clouds with high spatial and temporal resolution as they unfold across a large field of the sky. The project is motivated by the serendipitous observation of PMCs during the balloon flight of EBEX, an observational cosmology experiment which flew in 2013 at an altitude of about 35 km. EBEX included two star cameras, each of which had a field of view of 4 by 3 degrees, a resolution of 2.5 m at 80 km altitude, and an image cadence of 30 seconds. Even though EBEX was not designed to observe PMCs, instability and turbulent structures were visible with features at scales down to 20 m in the star camera images. However, it is difficult to put the images in context due to the inconsistent pointing, slow image cadence, and the narrow field of view. PMC-Turbo was designed leverage the strengths of the EBEX star cameras to observe gravity wave events at various length scales. This requires capturing a wide view while remaining sensitive to small features, as well as recording images at a high cadence. It carries seven cameras, four of which are wide field cameras that together cover a field of view of about 150 by 40 degrees with an 8 m per pixel resolution. Cameras with narrow field lenses provide smaller fields of view of 10 by 15 degrees with about 3 m per pixel resolution and are situated within in the larger field of view. The cameras can sustain 3.5 frames per second and can capture bursts of images up to 8 frames per second. The payload also carries BOLIDE, a Rayleigh lidar from the DLR Institute of Atmospheric Physics and an airglow camera from Utah State University. These instruments will provide additional context to observed events in the form of thermal profiles and infrared mapping. The Balloon Lidar Experiment BOLIDE is a miniaturized Rayleigh backscatter lidar developed for PMC-Turbo that will provide observations of PMC with unprecedented resolution and signal to noise ratio. PMC-Turbo is scheduled to fly next year from either Sweden or Antarctica. We anticipate a fourteen day flight over Antarctica, and we expect to capture about 14 million images. An arctic flight would last around 5 days, but we anticipate several gravity wave events during this time. In addition to lab testing of our equipment, we have had opportunities to collect data with the PMC-Turbo instruments in the field. This December we will fly one camera as a piggyback on the Super Tiger payload from Antarctica. In July, we used several cameras on the ground to capture PMC images in High Level, Alberta. We hope to resolve tomography from the images captured during that campaign. If we fly from Sweden, we plan to coordinate ground-based tomographic imaging with the balloon flight.
format Conference Object
author Kaifler, Bernd
Fritts, David C.
Miller, Amber
Limon, Michele
Jones, Glenn
Kjellstrand, Bjorn
Williams, Bifford P.
Wang, Ling
Reimuller, Jason
Hanany, Shaul
Geach, Christopher
Taylor, M.
author_facet Kaifler, Bernd
Fritts, David C.
Miller, Amber
Limon, Michele
Jones, Glenn
Kjellstrand, Bjorn
Williams, Bifford P.
Wang, Ling
Reimuller, Jason
Hanany, Shaul
Geach, Christopher
Taylor, M.
author_sort Kaifler, Bernd
title PMC-Turbo: a balloon-borne Mission to image gravity waves and turbulence in polar mesospheric clouds
title_short PMC-Turbo: a balloon-borne Mission to image gravity waves and turbulence in polar mesospheric clouds
title_full PMC-Turbo: a balloon-borne Mission to image gravity waves and turbulence in polar mesospheric clouds
title_fullStr PMC-Turbo: a balloon-borne Mission to image gravity waves and turbulence in polar mesospheric clouds
title_full_unstemmed PMC-Turbo: a balloon-borne Mission to image gravity waves and turbulence in polar mesospheric clouds
title_sort pmc-turbo: a balloon-borne mission to image gravity waves and turbulence in polar mesospheric clouds
publishDate 2017
url https://elib.dlr.de/114378/
https://elib.dlr.de/114378/1/1709_BK_PMCTurbo_LPMR.pdf
https://www.iap-kborn.de/fileadmin/user_upload/Current_issue/Workshops/LPMR2017/data/abstracts/abstract_73.html
geographic Arctic
geographic_facet Arctic
genre Antarc*
Antarctica
Arctic
genre_facet Antarc*
Antarctica
Arctic
op_relation https://elib.dlr.de/114378/1/1709_BK_PMCTurbo_LPMR.pdf
Kaifler, Bernd und Fritts, David C. und Miller, Amber und Limon, Michele und Jones, Glenn und Kjellstrand, Bjorn und Williams, Bifford P. und Wang, Ling und Reimuller, Jason und Hanany, Shaul und Geach, Christopher und Taylor, M. (2017) PMC-Turbo: a balloon-borne Mission to image gravity waves and turbulence in polar mesospheric clouds. 13th International Workshop on Layered Phenomena in the Mesopause Region (LPMR), 18.-22. Sep. 2017, Kühlungsborn, Germany. (nicht veröffentlicht)
_version_ 1766268883857047552
spelling ftdlr:oai:elib.dlr.de:114378 2023-05-15T13:59:58+02:00 PMC-Turbo: a balloon-borne Mission to image gravity waves and turbulence in polar mesospheric clouds Kaifler, Bernd Fritts, David C. Miller, Amber Limon, Michele Jones, Glenn Kjellstrand, Bjorn Williams, Bifford P. Wang, Ling Reimuller, Jason Hanany, Shaul Geach, Christopher Taylor, M. 2017-09-20 application/pdf https://elib.dlr.de/114378/ https://elib.dlr.de/114378/1/1709_BK_PMCTurbo_LPMR.pdf https://www.iap-kborn.de/fileadmin/user_upload/Current_issue/Workshops/LPMR2017/data/abstracts/abstract_73.html en eng https://elib.dlr.de/114378/1/1709_BK_PMCTurbo_LPMR.pdf Kaifler, Bernd und Fritts, David C. und Miller, Amber und Limon, Michele und Jones, Glenn und Kjellstrand, Bjorn und Williams, Bifford P. und Wang, Ling und Reimuller, Jason und Hanany, Shaul und Geach, Christopher und Taylor, M. (2017) PMC-Turbo: a balloon-borne Mission to image gravity waves and turbulence in polar mesospheric clouds. 13th International Workshop on Layered Phenomena in the Mesopause Region (LPMR), 18.-22. Sep. 2017, Kühlungsborn, Germany. (nicht veröffentlicht) Lidar Konferenzbeitrag NonPeerReviewed 2017 ftdlr 2019-08-04T22:59:45Z PMC-Turbo is a balloon-borne experiment that will fly at an altitude between 35 and 40 km. It is designed to record gravity wave events in polar mesospheric clouds with high spatial and temporal resolution as they unfold across a large field of the sky. The project is motivated by the serendipitous observation of PMCs during the balloon flight of EBEX, an observational cosmology experiment which flew in 2013 at an altitude of about 35 km. EBEX included two star cameras, each of which had a field of view of 4 by 3 degrees, a resolution of 2.5 m at 80 km altitude, and an image cadence of 30 seconds. Even though EBEX was not designed to observe PMCs, instability and turbulent structures were visible with features at scales down to 20 m in the star camera images. However, it is difficult to put the images in context due to the inconsistent pointing, slow image cadence, and the narrow field of view. PMC-Turbo was designed leverage the strengths of the EBEX star cameras to observe gravity wave events at various length scales. This requires capturing a wide view while remaining sensitive to small features, as well as recording images at a high cadence. It carries seven cameras, four of which are wide field cameras that together cover a field of view of about 150 by 40 degrees with an 8 m per pixel resolution. Cameras with narrow field lenses provide smaller fields of view of 10 by 15 degrees with about 3 m per pixel resolution and are situated within in the larger field of view. The cameras can sustain 3.5 frames per second and can capture bursts of images up to 8 frames per second. The payload also carries BOLIDE, a Rayleigh lidar from the DLR Institute of Atmospheric Physics and an airglow camera from Utah State University. These instruments will provide additional context to observed events in the form of thermal profiles and infrared mapping. The Balloon Lidar Experiment BOLIDE is a miniaturized Rayleigh backscatter lidar developed for PMC-Turbo that will provide observations of PMC with unprecedented resolution and signal to noise ratio. PMC-Turbo is scheduled to fly next year from either Sweden or Antarctica. We anticipate a fourteen day flight over Antarctica, and we expect to capture about 14 million images. An arctic flight would last around 5 days, but we anticipate several gravity wave events during this time. In addition to lab testing of our equipment, we have had opportunities to collect data with the PMC-Turbo instruments in the field. This December we will fly one camera as a piggyback on the Super Tiger payload from Antarctica. In July, we used several cameras on the ground to capture PMC images in High Level, Alberta. We hope to resolve tomography from the images captured during that campaign. If we fly from Sweden, we plan to coordinate ground-based tomographic imaging with the balloon flight. Conference Object Antarc* Antarctica Arctic German Aerospace Center: elib - DLR electronic library Arctic

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