Generation of Short-scale Electrostatic Fields in the Solar Atmosphere and the Role of Helium Ions

Theoretical models are presented to show that expansion of plasma in the radial direction from a denser solar surface to a rarefied upper atmosphere with short-scale inhomogeneous field-aligned flows and currents in the form of thin threads itself is an important source of electrostatic instabilitie...

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Bibliographic Details
Published in:The Astrophysical journal 2021-11, Vol.922 (1), p.48
Main Authors: Saleem, H., Shan, Shaukat Ali, Rehman, A.
Format: Article
Language:English
Subjects:
Astrophysics
Atmosphere
Atmospheric models
Corona
Current sheets
Electric fields
Filaments
Growth rate
Helium
Helium ions
Hydrogen
Hydrogen ions
Hydrogen plasma
Kinetic theory
Particle interactions
Plasma
Shear flow
Solar atmosphere
Solar corona
Solar coronal waves
Solar surface
Upper atmosphere
Wavelengths
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Summary:Theoretical models are presented to show that expansion of plasma in the radial direction from a denser solar surface to a rarefied upper atmosphere with short-scale inhomogeneous field-aligned flows and currents in the form of thin threads itself is an important source of electrostatic instabilities. Multifluid theory shows that the shear flow–driven purely growing electric fields appear in the transition region. On the other hand, plasma kinetic theory predicts that the short-scale current sheets (or filaments) produce current-driven electrostatic ion acoustic (CDEIA) waves in the hydrogen plasma of the transition region that damp out in the system through wave–particle interactions and increase the temperature. Similar processes take place in the solar corona and act positively for increasing the temperature further and maintaining it. The shear flow–driven instabilities and CDEIA waves have short perpendicular wavelengths of the order of 1 m and low frequencies of the order of 1 or several Hz when the ions’ shear flow scale length is considered to be of the order of 1 km. It is pointed out that the purely growing fluid instabilities turn into oscillatory instabilities and the growth rates of kinetic CDEIA wave instabilities are reduced when the dynamics of 10% helium ions is taken into account along with 90% hydrogen ions. Therefore, the role of helium ions should not be ignored in the study of wave dynamics in solar plasma.
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/ac05cb