Nightside Detection of a Large‐Scale Thermospheric Wave Generated by a Solar Eclipse

The generation of a large‐scale wave in the upper atmosphere caused by a solar eclipse was first predicted in the 1970s, but the experimental evidence remains sparse and comprises mostly indirect observations. This study presents observations of the wind component of a large‐scale thermospheric wave...

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Bibliographic Details
Published in:Geophysical research letters 2018-04, Vol.45 (8), p.3366-3373
Main Authors: Harding, B. J., Drob, D. P., Buriti, R. A., Makela, J. J.
Format: Article
Language:English
Subjects:
Airglow
Atmosphere
Atmospheric models
Boats
Detection
Doppler effect
Doppler sonar
Earth
Eclipse effects
Eclipses
Electrodynamics
Emission measurements
First principles
General circulation models
Interferometers
Ionosphere
Ionospheric propagation
Mathematical models
Meridional wind
Mesosphere
Moon
Numerical models
Physics
Predictions
Scale (ratio)
Shadows
Sinkholes
solar eclipse
Solar eclipses
Temperature data
Temperature effects
Thermosphere
thermospheric wave
thermospheric wind
Upper atmosphere
Wave propagation
Wind measurement
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Summary:The generation of a large‐scale wave in the upper atmosphere caused by a solar eclipse was first predicted in the 1970s, but the experimental evidence remains sparse and comprises mostly indirect observations. This study presents observations of the wind component of a large‐scale thermospheric wave generated by the 21 August 2017 total solar eclipse. In contrast with previous studies, the observations are made on the nightside, after the eclipse ended. A ground‐based interferometer located in northeastern Brazil is used to monitor the Doppler shift of the 630.0‐nm airglow emission, providing direct measurements of the wind and temperature in the thermosphere, where eclipse effects are expected to be the largest. A disturbance is seen in the zonal and meridional wind which is at or above the 90% significance level based on the measured 30‐day variability. These observations are compared with a first principles numerical model calculation from the Thermosphere‐Ionosphere‐Mesosphere‐Electrodynamics General Circulation Model, which predicted the propagation of a large‐scale wave well into the nightside. The modeled disturbance matches well the difference between the wind measurements and the 30‐day median, though the measured perturbation (∼60 m/s) is larger than the prediction (38 m/s) for the meridional wind. No clear evidence for the wave is seen in the temperature data, however. Plain Language Summary Solar eclipses are natural experiments that allow us to test our models of the upper atmosphere. It has long been theorized that during a solar eclipse, the fast motion of the Moon's shadow across the Earth should cause a wave in the upper atmosphere, similar to the bow wave that develops in front of a boat. In contrast with the boat, which pushes water ahead of it, the cold atmosphere inside the shadow acts like a sinkhole that pulls the air ahead of it. In this paper, we report the first direct observations of the atmosphere moving in response to an eclipse, using data taken during and after the Great American eclipse on 21 August 2017. These observations match well the predictions made by a commonly used upper atmosphere model, in both the timing and size of the response. An interesting aspect of these observations is that they were made in Brazil, after the eclipse had ended, emphasizing the global nature of the eclipse response. This study is important because it provides direct evidence to support previous theoretical eclipse studies, and it furthers o
ISSN:0094-8276
1944-8007
DOI:10.1002/2018GL077015