The MaCWAVE program to study gravity wave influences on the polar mesosphere

MaCWAVE ( M ountain a nd C onvective W aves A scending VE rtically) was a highly coordinated rocket, ground-based, and satellite program designed to address gravity wave forcing of the mesosphere and lower thermosphere (MLT). The MaCWAVE program was conducted at the Norwegian Andøya Rocket Range (AR...

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Published in:Annales Geophysicae
Main Authors: Goldberg, R. A., Fritts, D. C., Schmidlin, F. J., Williams, B. P., Croskey, C. L., Mitchell, J. D., Friedrich, M., Russell, J. M., Blum, U., Fricke, K. H.
Format: Text
Language:English
Published: 2018
Subjects:
Alomar
Andøya
Esrange
Norway
Orion
Online Access:https://doi.org/10.5194/angeo-24-1159-2006
https://angeo.copernicus.org/articles/24/1159/2006/
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institution Open Polar
collection Copernicus Publications: E-Journals
op_collection_id ftcopernicus
language English
description MaCWAVE ( M ountain a nd C onvective W aves A scending VE rtically) was a highly coordinated rocket, ground-based, and satellite program designed to address gravity wave forcing of the mesosphere and lower thermosphere (MLT). The MaCWAVE program was conducted at the Norwegian Andøya Rocket Range (ARR, 69.3° N) in July2002, and continued at the Swedish Rocket Range (Esrange, 67.9° N) during January 2003. Correlative instrumentation included the ALOMAR MF and MST radars and RMR and Na lidars, Esrange MST and meteor radars and RMR lidar, radiosondes, and TIMED ( T hermosphere I onosphere M esosphere E nergetics and D ynamics) satellite measurements of thermal structures. The data have been used to define both the mean fields and the wave field structures and turbulence generation leading to forcing of the large-scale flow. In summer, launch sequences coupled with ground-based measurements at ARR addressed the forcing of the summer mesopause environment by anticipated convective and shear generated gravity waves. These motions were measured with two 12-h rocket sequences, each involving one Terrier-Orion payload accompanied by a mix of MET rockets, all at ARR in Norway. The MET rockets were used to define the temperature and wind structure of the stratosphere and mesosphere. The Terrier-Orions were designed to measure small-scale plasma fluctuations and turbulence that might be induced by wave breaking in the mesosphere. For the summer series, three European MIDAS ( Mi ddle Atmosphere D ynamics a nd S tructure) rockets were also launched from ARR in coordination with the MaCWAVE payloads. These were designed to measure plasma and neutral turbulence within the MLT. The summer program exhibited a number of indications of significant departures of the mean wind and temperature structures from ``normal" polar summer conditions, including an unusually warm mesopause and a slowing of the formation of polar mesospheric summer echoes (PMSE) and noctilucent clouds (NLC). This was suggested to be due to enhanced planetary wave activity in the Southern Hemisphere and a surprising degree of inter-hemispheric coupling. The winter program was designed to study the upward propagation and penetration of mountain waves from northern Scandinavia into the MLT at a site favored for such penetration. As the major response was expected to be downstream (east) of Norway, these motions were measured with similar rocket sequences to those used in the summer campaign, but this time at Esrange. However, a major polar stratospheric warming just prior to the rocket launch window induced small or reversed stratospheric zonal winds, which prevented mountain wave penetration into the mesosphere. Instead, mountain waves encountered critical levels at lower altitudes and the observed wave structure in the mesosphere originated from other sources. For example, a large-amplitude semidiurnal tide was observed in the mesosphere on 28 and 29January, and appears to have contributed to significant instability and small-scale structures at higher altitudes. The resulting energy deposition was found to be competitive with summertime values. Hence, our MaCWAVE measurements as a whole are the first to characterize influences in the MLT region of planetary wave activity and related stratospheric warmings during both winter and summer.
format Text
author Goldberg, R. A.
Fritts, D. C.
Schmidlin, F. J.
Williams, B. P.
Croskey, C. L.
Mitchell, J. D.
Friedrich, M.
Russell, J. M.
Blum, U.
Fricke, K. H.
spellingShingle Goldberg, R. A.
Fritts, D. C.
Schmidlin, F. J.
Williams, B. P.
Croskey, C. L.
Mitchell, J. D.
Friedrich, M.
Russell, J. M.
Blum, U.
Fricke, K. H.
The MaCWAVE program to study gravity wave influences on the polar mesosphere
author_facet Goldberg, R. A.
Fritts, D. C.
Schmidlin, F. J.
Williams, B. P.
Croskey, C. L.
Mitchell, J. D.
Friedrich, M.
Russell, J. M.
Blum, U.
Fricke, K. H.
author_sort Goldberg, R. A.
title The MaCWAVE program to study gravity wave influences on the polar mesosphere
title_short The MaCWAVE program to study gravity wave influences on the polar mesosphere
title_full The MaCWAVE program to study gravity wave influences on the polar mesosphere
title_fullStr The MaCWAVE program to study gravity wave influences on the polar mesosphere
title_full_unstemmed The MaCWAVE program to study gravity wave influences on the polar mesosphere
title_sort macwave program to study gravity wave influences on the polar mesosphere
publishDate 2018
url https://doi.org/10.5194/angeo-24-1159-2006
https://angeo.copernicus.org/articles/24/1159/2006/
long_lat ENVELOPE(-67.083,-67.083,-68.133,-68.133)
ENVELOPE(13.982,13.982,68.185,68.185)
ENVELOPE(21.117,21.117,67.883,67.883)
ENVELOPE(-59.800,-59.800,-62.438,-62.438)
geographic Alomar
Andøya
Esrange
Norway
Orion
geographic_facet Alomar
Andøya
Esrange
Norway
Orion
genre Andøya
genre_facet Andøya
op_source eISSN: 1432-0576
op_relation doi:10.5194/angeo-24-1159-2006
https://angeo.copernicus.org/articles/24/1159/2006/
op_doi https://doi.org/10.5194/angeo-24-1159-2006
container_title Annales Geophysicae
container_volume 24
container_issue 4
container_start_page 1159
op_container_end_page 1173
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spelling ftcopernicus:oai:publications.copernicus.org:angeo35843 2023-05-15T13:25:46+02:00 The MaCWAVE program to study gravity wave influences on the polar mesosphere Goldberg, R. A. Fritts, D. C. Schmidlin, F. J. Williams, B. P. Croskey, C. L. Mitchell, J. D. Friedrich, M. Russell, J. M. Blum, U. Fricke, K. H. 2018-09-27 application/pdf https://doi.org/10.5194/angeo-24-1159-2006 https://angeo.copernicus.org/articles/24/1159/2006/ eng eng doi:10.5194/angeo-24-1159-2006 https://angeo.copernicus.org/articles/24/1159/2006/ eISSN: 1432-0576 Text 2018 ftcopernicus https://doi.org/10.5194/angeo-24-1159-2006 2020-07-20T16:27:15Z MaCWAVE ( M ountain a nd C onvective W aves A scending VE rtically) was a highly coordinated rocket, ground-based, and satellite program designed to address gravity wave forcing of the mesosphere and lower thermosphere (MLT). The MaCWAVE program was conducted at the Norwegian Andøya Rocket Range (ARR, 69.3° N) in July2002, and continued at the Swedish Rocket Range (Esrange, 67.9° N) during January 2003. Correlative instrumentation included the ALOMAR MF and MST radars and RMR and Na lidars, Esrange MST and meteor radars and RMR lidar, radiosondes, and TIMED ( T hermosphere I onosphere M esosphere E nergetics and D ynamics) satellite measurements of thermal structures. The data have been used to define both the mean fields and the wave field structures and turbulence generation leading to forcing of the large-scale flow. In summer, launch sequences coupled with ground-based measurements at ARR addressed the forcing of the summer mesopause environment by anticipated convective and shear generated gravity waves. These motions were measured with two 12-h rocket sequences, each involving one Terrier-Orion payload accompanied by a mix of MET rockets, all at ARR in Norway. The MET rockets were used to define the temperature and wind structure of the stratosphere and mesosphere. The Terrier-Orions were designed to measure small-scale plasma fluctuations and turbulence that might be induced by wave breaking in the mesosphere. For the summer series, three European MIDAS ( Mi ddle Atmosphere D ynamics a nd S tructure) rockets were also launched from ARR in coordination with the MaCWAVE payloads. These were designed to measure plasma and neutral turbulence within the MLT. The summer program exhibited a number of indications of significant departures of the mean wind and temperature structures from ``normal" polar summer conditions, including an unusually warm mesopause and a slowing of the formation of polar mesospheric summer echoes (PMSE) and noctilucent clouds (NLC). This was suggested to be due to enhanced planetary wave activity in the Southern Hemisphere and a surprising degree of inter-hemispheric coupling. The winter program was designed to study the upward propagation and penetration of mountain waves from northern Scandinavia into the MLT at a site favored for such penetration. As the major response was expected to be downstream (east) of Norway, these motions were measured with similar rocket sequences to those used in the summer campaign, but this time at Esrange. However, a major polar stratospheric warming just prior to the rocket launch window induced small or reversed stratospheric zonal winds, which prevented mountain wave penetration into the mesosphere. Instead, mountain waves encountered critical levels at lower altitudes and the observed wave structure in the mesosphere originated from other sources. For example, a large-amplitude semidiurnal tide was observed in the mesosphere on 28 and 29January, and appears to have contributed to significant instability and small-scale structures at higher altitudes. The resulting energy deposition was found to be competitive with summertime values. Hence, our MaCWAVE measurements as a whole are the first to characterize influences in the MLT region of planetary wave activity and related stratospheric warmings during both winter and summer. Text Andøya Copernicus Publications: E-Journals Alomar ENVELOPE(-67.083,-67.083,-68.133,-68.133) Andøya ENVELOPE(13.982,13.982,68.185,68.185) Esrange ENVELOPE(21.117,21.117,67.883,67.883) Norway Orion ENVELOPE(-59.800,-59.800,-62.438,-62.438) Annales Geophysicae 24 4 1159 1173

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