Journal article
Solar Rotation Period Driven Modulations of Plasmaspheric Density and Convective Electric Field in the Inner Magnetosphere
Journal of geophysical research. Space physics, Vol.124(3), pp.1726-1737
03/2019
DOI: 10.1029/2018JA026365
Abstract
This paper presents the first analysis of Van Allen Probes measurements of the cold plasma density and electric field in the inner magnetosphere to show that intervals of strong modulation at the solar rotation period occur in the locations of the outer plasmasphere and plasmapause (~0.7 RE peak‐to‐peak), in the large‐scale electric field (~0.24 mV/m peak‐to‐peak), and in the cold plasma density (~250 to ~70 cm−3 peak‐to‐peak). Solar rotation modulation of the inner magnetosphere is more apparent in the declining phase of the solar cycle than near solar maximum. The periodicities in these parameters are compared to solar extreme ultraviolet irradiance, solar wind dawn‐dusk electric field, and Kp. The variations in the plasmapause location at the solar rotation period anticorrelate with solar wind electric field, magnetospheric electric field, and Kp, but not with extreme ultraviolet irradiance, indicating that convective erosion is the dominant physical process controlling the plasmapause at these timescales.
Plain Language Summary
As the Sun rotates with a 27‐day period, it also emits winds of ionized gas. In some places these winds are leaving at faster speeds than in other places. These winds flow out to the Earth and beyond, and because the Sun rotates, the Earth is hit with each stream of fast wind every 27 days. A region of cooler ionized gas in space surrounding Earth, called the plasmasphere, shrinks when the effects of the fast wind on Earth's magnetic field cause the removal of the outer part of the plasmasphere. When the wind speeds decrease, the plasmasphere grows in size again. The result is that the plasmasphere breathes in and out at the solar rotation period. We use the Van Allen Probe‐B satellite to measure the size and density of the plasmasphere and to show for the first time with direct measurements the 27‐day variation in the plasmasphere and its connection to the fast winds from the Sun. This result is important, as the behavior of the plasmasphere affects various kinds of waves that can exist in space around Earth, some of which are responsible for the creation and loss of energetic electrons that can damage spacecraft.
Key Points
The dawn‐dusk electric field, plasmaspheric density, and plasmapause L value are driven at near the solar rotation period, ~27 days
The solar rotation periodicity in plasmaspheric densities and plasmapause L value is due to magnetospheric convection
Convective driving of the inner magnetosphere at the solar rotation period is more dominant in the declining phase of the solar cycle
Details
- Title: Subtitle
- Solar Rotation Period Driven Modulations of Plasmaspheric Density and Convective Electric Field in the Inner Magnetosphere
- Creators
- S. A. Thaller - Laboratory for Atmospheric and Space PhysicsJ. R. Wygant - University of MinnesotaC. A. Cattell - University of MinnesotaA. W. Breneman - University of MinnesotaE. Tyler - University of MinnesotaS. Tian - University of MinnesotaA. Engel - University of Colorado BoulderS. De Pascuale - University of IowaW. S. Kurth - University of IowaC. A. Kletzing - University of IowaJ. Tears - University of MinnesotaDavid M. Malaspina - Laboratory for Atmospheric and Space Physics
- Resource Type
- Journal article
- Publication Details
- Journal of geophysical research. Space physics, Vol.124(3), pp.1726-1737
- DOI
- 10.1029/2018JA026365
- ISSN
- 2169-9380
- eISSN
- 2169-9402
- Number of pages
- 12
- Grant note
- NASA (APL NAS5‐01072) JHU | Applied Physics Laboratory, Johns Hopkins University (APL, JHU) (922613; 921647)
- Language
- English
- Date published
- 03/2019
- Academic Unit
- Physics and Astronomy
- Record Identifier
- 9984428773702771
Metrics
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