Multifluid Simulation of Solar Chromospheric Turbulence and Heating Due to Thermal Farley–Buneman Instability

Evans, Samuel Lewin; Oppenheim, M. M.; Martínez-Sykora, Juan; Dimant, Y. S.; Xiao, Richard

doi:10.3847/1538-4357/acc5e5

ApJ

2023

DOI: 10.3847/1538-4357/acc5e5

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Multifluid Simulation of Solar Chromospheric Turbulence and Heating Due to Thermal Farley–Buneman Instability

Samuel Lewin Evans

M. M. Oppenheim

Juan Martínez-Sykora

et al.

Abstract: Models fail to reproduce observations of the coldest parts of the Sun’s atmosphere, where interactions between multiple ionized and neutral species prevent an accurate MHD representation. This paper argues that a meter-scale electrostatic plasma instability develops in these regions and causes heating. We refer to this instability as the Thermal Farley–Buneman Instability (TFBI). Using parameters from a 2.5D radiative MHD Bifrost simulation, we show that the TFBI develops in many of the colder regions in the c… Show more

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Unified fluid theory of the collisional thermal Farley–Buneman instability including magnetized multi-species ions

Dimant,

Oppenheim,

Evans

et al. 2023

Physics of Plasmas

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This paper develops a unified linear theory of cross field plasma instabilities, including the Farley–Buneman, electron thermal, and ion thermal instabilities, in spatially uniform collisional plasmas with partially unmagnetized multi-species ions. Collisional plasma instabilities in weakly ionized, highly dissipative, weakly magnetized plasmas play an important role in the lower Earth's ionosphere and may be of importance in other planetary ionospheres, stellar atmospheres, cometary tails, molecular clouds, accretion disks, etc. In the Earth's ionosphere, these collisional plasma instabilities cause intense electron heating. In the solar chromosphere, they can do the same—an effect originally suggested from spectroscopic observations and modeling. Based on a simplified 5-moment multi-fluid model, the theoretical analysis presented in this paper produces the linear dispersion relation for the combined Thermal Farley–Buneman Instability with an important long-wavelength limit analyzed in detail. This limit provides an easy interpretation of different instability drivers and wave dissipation. This analysis of instability, combined with simulations, will enable us to better understand plasma waves and turbulence in these commonly occurring collisional space plasmas.

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Unified fluid theory of the collisional thermal Farley–Buneman instability including magnetized multi-species ions

Dimant,

Oppenheim,

Evans

et al. 2023

Physics of Plasmas

View full text Add to dashboard Cite

show abstract

Deriving improved plasma fluid equations from collisional kinetic theory

Dimant

2024

Front. Astron. Space Sci.

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IntroductionDeveloping a quantitative understanding of wave plasma processes in the lower ionosphere requires a reasonably accurate theoretical description of the underlying physical processes. For such a highly collisional plasma environment as the E-region ionosphere, kinetic theory represents the most accurate theoretical description of wave processes. For the analytical treatment, however, collisional kinetic theory is extremely complicated and succeeds only in a limited number of physical problems. To date, most research has applied oversimplified fluid models that lack a number of critical kinetic aspects, so the coefficients in the corresponding fluid equations are often accurate only to an order of magnitude.MethodsThis paper presents a derivation for the highly collisional, partially magnetized case relevant to E-region conditions, using methods of the collisional kinetic theory with a new set of analytic approximations.ResultsThis derivation provides a more accurate reduction of the ion and, especially, electron kinetic equations to the corresponding 5-moment fluid equations. It results in a more accurate fluid model set of equations appropriate for most E-region problems.DiscussionThe results of this paper could be used for a routine practical analysis when working with actual data. The improved equations can also serve as a basis for more accurate plasma fluid computer simulations.

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Multifluid Simulation of Solar Chromospheric Turbulence and Heating Due to Thermal Farley–Buneman Instability

Cited by 2 publications

References 40 publications

Unified fluid theory of the collisional thermal Farley–Buneman instability including magnetized multi-species ions

Unified fluid theory of the collisional thermal Farley–Buneman instability including magnetized multi-species ions

Deriving improved plasma fluid equations from collisional kinetic theory

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