Spatial structure of the 12-hour wave in the Antarctic as observed by radar

We present radar measurements of the 12-hour wave, a zonal wavenumber 1 westward propagating wave that exists in the southern polar mesopause region winds (Hernandez et al, 1993; Forbes et al, 1995). MF radar measurements of the horizontal winds at McMurdo (77.8° S, 166.67° E) show that the 12-hour...

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Main Authors: Riggin, D. M., Fritts, D. C., Jarvis, M. J., Jones, G. O. L.
Format: Article in Journal/Newspaper
Language:unknown
Published: 1999
Subjects:
Antarctic
The Antarctic
Austral
Forbes
Hernandez
Antarc*
Online Access:http://nora.nerc.ac.uk/id/eprint/503766/
http://www.terrapub.co.jp/journals/EPS/abstract/5107_08/51070621.html
id ftnerc:oai:nora.nerc.ac.uk:503766
record_format openpolar
spelling ftnerc:oai:nora.nerc.ac.uk:503766 2023-05-15T13:48:08+02:00 Spatial structure of the 12-hour wave in the Antarctic as observed by radar Riggin, D. M. Fritts, D. C. Jarvis, M. J. Jones, G. O. L. 1999 http://nora.nerc.ac.uk/id/eprint/503766/ http://www.terrapub.co.jp/journals/EPS/abstract/5107_08/51070621.html unknown Riggin, D. M.; Fritts, D. C.; Jarvis, M. J.; Jones, G. O. L. 1999 Spatial structure of the 12-hour wave in the Antarctic as observed by radar. Earth, Planets and Space, 51 (7-8). 621-628. Publication - Article PeerReviewed 1999 ftnerc 2023-02-04T19:38:02Z We present radar measurements of the 12-hour wave, a zonal wavenumber 1 westward propagating wave that exists in the southern polar mesopause region winds (Hernandez et al, 1993; Forbes et al, 1995). MF radar measurements of the horizontal winds at McMurdo (77.8° S, 166.67° E) show that the 12-hour wave is highly seasonal, occurring during the austral summer solstice. During these seasonal occurrences, the wave is highly intermittent with amplitude peaks of 30 m s-1. The burst-like occurrences of large 12-hour wave amplitudes are highly correlated between the zonal and meridional direction. The diurnal tide over McMurdo has a more constant amplitude, but it is also an almost exclusively summertime phenomenon. Inertia-gravity wave activity is evident at periods less than 12 hr during the austral winter months. The weakening of gravity wave activity during the summer is probably due to critical layer filtering by the zonal mean wind, 12-hour wave and diurnal tide which are all strong during this season. The 12-hour wave is confined in height to the vicinity of the zero crossing in the zonal winds above the westward jet. Extreme distortion is observed in the vertical phase fronts of the 12-hour wave which could signify either refraction or in situ forcing. The distortion in the phase fronts and localization of the 12-hour wave in time and height is apparently responsible for departures in period from the nominal 12 hours. We do not find the wave period to be systematically different from 12 hours. The association of the 12-hour wave events with shear in the mean wind suggests that refractive effects could conceivably cause a dilation in wave amplitude. However, the shear is of the opposite sign to cause this dilation unless the wave originates at higher altitudes and propagates downward into the mesosphere. Investigations are made of the zonal structure of the 12-hour wave by comparing phases of the 12-hour wind component between McMurdo and the dynasonde at Halley (75.8° S, 26.4° W). The phase is found to be ... Article in Journal/Newspaper Antarc* Antarctic Natural Environment Research Council: NERC Open Research Archive Antarctic The Antarctic Austral Forbes ENVELOPE(-66.550,-66.550,-67.783,-67.783) Hernandez ENVELOPE(-62.167,-62.167,-74.500,-74.500)
institution Open Polar
collection Natural Environment Research Council: NERC Open Research Archive
op_collection_id ftnerc
language unknown
description We present radar measurements of the 12-hour wave, a zonal wavenumber 1 westward propagating wave that exists in the southern polar mesopause region winds (Hernandez et al, 1993; Forbes et al, 1995). MF radar measurements of the horizontal winds at McMurdo (77.8° S, 166.67° E) show that the 12-hour wave is highly seasonal, occurring during the austral summer solstice. During these seasonal occurrences, the wave is highly intermittent with amplitude peaks of 30 m s-1. The burst-like occurrences of large 12-hour wave amplitudes are highly correlated between the zonal and meridional direction. The diurnal tide over McMurdo has a more constant amplitude, but it is also an almost exclusively summertime phenomenon. Inertia-gravity wave activity is evident at periods less than 12 hr during the austral winter months. The weakening of gravity wave activity during the summer is probably due to critical layer filtering by the zonal mean wind, 12-hour wave and diurnal tide which are all strong during this season. The 12-hour wave is confined in height to the vicinity of the zero crossing in the zonal winds above the westward jet. Extreme distortion is observed in the vertical phase fronts of the 12-hour wave which could signify either refraction or in situ forcing. The distortion in the phase fronts and localization of the 12-hour wave in time and height is apparently responsible for departures in period from the nominal 12 hours. We do not find the wave period to be systematically different from 12 hours. The association of the 12-hour wave events with shear in the mean wind suggests that refractive effects could conceivably cause a dilation in wave amplitude. However, the shear is of the opposite sign to cause this dilation unless the wave originates at higher altitudes and propagates downward into the mesosphere. Investigations are made of the zonal structure of the 12-hour wave by comparing phases of the 12-hour wind component between McMurdo and the dynasonde at Halley (75.8° S, 26.4° W). The phase is found to be ...
format Article in Journal/Newspaper
author Riggin, D. M.
Fritts, D. C.
Jarvis, M. J.
Jones, G. O. L.
spellingShingle Riggin, D. M.
Fritts, D. C.
Jarvis, M. J.
Jones, G. O. L.
Spatial structure of the 12-hour wave in the Antarctic as observed by radar
author_facet Riggin, D. M.
Fritts, D. C.
Jarvis, M. J.
Jones, G. O. L.
author_sort Riggin, D. M.
title Spatial structure of the 12-hour wave in the Antarctic as observed by radar
title_short Spatial structure of the 12-hour wave in the Antarctic as observed by radar
title_full Spatial structure of the 12-hour wave in the Antarctic as observed by radar
title_fullStr Spatial structure of the 12-hour wave in the Antarctic as observed by radar
title_full_unstemmed Spatial structure of the 12-hour wave in the Antarctic as observed by radar
title_sort spatial structure of the 12-hour wave in the antarctic as observed by radar
publishDate 1999
url http://nora.nerc.ac.uk/id/eprint/503766/
http://www.terrapub.co.jp/journals/EPS/abstract/5107_08/51070621.html
long_lat ENVELOPE(-66.550,-66.550,-67.783,-67.783)
ENVELOPE(-62.167,-62.167,-74.500,-74.500)
geographic Antarctic
The Antarctic
Austral
Forbes
Hernandez
geographic_facet Antarctic
The Antarctic
Austral
Forbes
Hernandez
genre Antarc*
Antarctic
genre_facet Antarc*
Antarctic
op_relation Riggin, D. M.; Fritts, D. C.; Jarvis, M. J.; Jones, G. O. L. 1999 Spatial structure of the 12-hour wave in the Antarctic as observed by radar. Earth, Planets and Space, 51 (7-8). 621-628.
_version_ 1766248699771486208

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