Solar Faculae: Microturbulence as an Indicator of Inclined Magnetic Fields

— The observations of the solar facula in the Ba II λ 455.403 Å line are used to construct a 3D model of the facula area by solving the inverse nonequilibrium radiative transfer problem and to investigate the fine structure of the field of unresolved velocities (microturbulence). New turbulent struc...

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Bibliographic Details
Published in:Kinematics and physics of celestial bodies 2020-07, Vol.36 (4), p.153-160
Main Authors: Stodilka, M. I., Kostyk, R. I.
Format: Article
Language:English
Subjects:
Anisotropy
Astronomy
Blurring
Chromosphere
Computational fluid dynamics
Faculae
Fine structure
Magnetic anisotropy
Magnetic fields
Observations and Techniques
Photosphere
Physics
Physics and Astronomy
Radiative transfer
Solar faculae
Solar magnetic field
Solar Physics
Three dimensional models
Turbulence
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Summary:— The observations of the solar facula in the Ba II λ 455.403 Å line are used to construct a 3D model of the facula area by solving the inverse nonequilibrium radiative transfer problem and to investigate the fine structure of the field of unresolved velocities (microturbulence). New turbulent structures are formed in the layers of the upper photosphere. They are localized mainly between upward and downward flows with the formation of ring-shaped structures of increased turbulence around these flows. The mechanism of magnetic anisotropy of microturbulent velocity is proposed (small-scale eddy-type plasma motions mainly occur in the planes perpendicular to the magnetic field), which explains the height dependence of the field of unresolved velocities. Anisotropy of microturbulence begins to manifest itself in the lower photospheric layers outside the upward and downward flows, while it manifests itself in the higher layers inside these flows. The increase of microturbulence in the layers of the upper photosphere and the lower chromosphere in the areas between matter flows indicates the presence of inclined magnetic fields, which, along with the blurring of its spatial structure, indicates the existence of a magnetic canopy region. Microturbulence can be used as an additional tool for diagnostics of inclined magnetic fields.
ISSN:0884-5913
1934-8401
DOI:10.3103/S0884591320040054