Detection of meteor radar wind signatures related to strong short-duration day-to-day airglow transitions at sites 2600 km apart

Bursts of strong day-to-day variations in airglow brightness and temperature for the mesopause region that last one or a few nights have frequently been observed at El Leoncito (LEO; 31.8°S 69.2°W), since 1997. After the start of the operation of the meteor wind radar at Cachoeira Paulista (CAP; 22....

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Bibliographic Details
Published in:Journal of atmospheric and solar-terrestrial physics 2005-04, Vol.67 (6), p.611-621
Main Authors: Scheer, J., Reisin, E.R., Batista, P.P., Clemesha, B.R., Takahashi, H.
Format: Article
Language:English
Subjects:
Airglow
Atmospheric dynamics
Earth, ocean, space
Exact sciences and technology
External geophysics
Mesopause region
Meteor radar
Physics of the high neutral atmosphere
Physics of the ionosphere
Physics of the magnetosphere
Solitons
Winds
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Summary:Bursts of strong day-to-day variations in airglow brightness and temperature for the mesopause region that last one or a few nights have frequently been observed at El Leoncito (LEO; 31.8°S 69.2°W), since 1997. After the start of the operation of the meteor wind radar at Cachoeira Paulista (CAP; 22.7°S 45.0°W, about 2600 km further NNE) in March 1999, a number of the strongest airglow events at LEO were found to be followed, 1–3 days later, by negative (westward) zonal wind excursions of about - 30 m / s that seem to be related. Meridional wind disturbances are absent or only weak. The zonal wind perturbation at CAP closely matches the altitude range defined by the airglow emission at LEO, i.e. an OH emission event corresponds to a lower-altitude wind signature, and an O 2 emission event, to one at a higher altitude. The strong differences in seasonal occurrence patterns of airglow bursts at LEO observed earlier (with O 2 bursts peaking in April, and OH bursts, in June) are confirmed by the more recent data presented here. Most of the observed features of the two-site events could be explained by anticyclonic vortices (with 2000 km diameter) propagating zonally with the eastward background wind. International collaborations like the Global Airglow Transition Detection and Tracking (GATDAT) campaign are expected to provide the information required to further the understanding of these phenomena.
ISSN:1364-6826
1879-1824
DOI:10.1016/j.jastp.2004.12.007