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- Title
Dependence of Dayside Electron Densities at Venus on Solar Irradiance.
- Authors
Hensley, K.; Withers, P.; Girazian, Z.; Pätzold, M.; Tellmann, S.; Häusler, B.
- Abstract
The ionosphere of Venus is a weakly ionized plasma layer embedded in the planet's upper atmosphere. Planetary ionospheres provide an excellent opportunity to study how our variable Sun affects the planets in our solar system. Because ionospheres are reservoirs from which atmospheric species can be lost to space, studying how ionospheres respond to changes in solar activity can help us understand how planetary atmospheres have evolved since their formation. While variations of the main and lower ionospheric peaks of Venus have been well studied, the behavior of the ionosphere above the altitude of the greatest electron density has not been fully constrained. To investigate the behavior of this region, we use electron density profiles obtained by the Venus Radio Science experiment aboard Venus Express. An increase in the response of the electron density to increasing solar irradiance with increasing altitude above the peak is readily apparent in these data. By using a one‐dimensional photochemical equilibrium model to investigate the factors that drive the variations of the ionosphere of Venus, we find that changes in the composition of the underlying neutral atmosphere are responsible for the observed increase in ionospheric response with altitude. Key Points: Electron densities in Venus's ionosphere respond more strongly to solar activity changes with increasing altitude above the ionospheric peakPhotochemical models are used to reproduce observed electron density profiles and assess causes of this behaviorLarge‐scale inflation of the neutral atmosphere with increasing solar activity causes the enhanced response with increasing altitude
- Subjects
VENUS (Planet); SPECTRAL irradiance; PLANETARY ionospheres; ELECTRON density; SOLAR activity
- Publication
Journal of Geophysical Research. Space Physics, 2020, Vol 125, Issue 2, p1
- ISSN
2169-9380
- Publication type
Article
- DOI
10.1029/2019JA027167