Thomson Scattering above Solar Active Regions and an Ad Hoc Polarization Correction Method for the Emissive Corona

Abstract Thomson-scattered photospheric light is the dominant constituent of the lower solar corona’s spectral continuum viewed off-limb at optical wavelengths. Known as the K-corona, it is also linearly polarized. We investigate the possibility of using the a priori polarized characteristics of the...

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Published inThe Astrophysical journal Vol. 933; no. 1; pp. 53 - 64
Main Authors Schad, Thomas A., Jaeggli, Sarah A., Dima, Gabriel I.
Format Journal Article
LanguageEnglish
Published Philadelphia The American Astronomical Society 01.07.2022
IOP Publishing
Subjects
Astrophysics
Broken symmetry
Corona
Crosstalk
Emission
Emission lines
Emission measurements
Fluid flow
Incident radiation
Induced polarization
Linear polarization
Magnetohydrodynamics
Photosphere
Polarization
Radiation
Solar activity
Solar activity regions
Solar corona
Solar E corona
Solar K corona
Solar magnetic fields
Spectropolarimetry
Stokes parameters
Tensors
Thomson scattering
Wavelengths
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Abstract Abstract Thomson-scattered photospheric light is the dominant constituent of the lower solar corona’s spectral continuum viewed off-limb at optical wavelengths. Known as the K-corona, it is also linearly polarized. We investigate the possibility of using the a priori polarized characteristics of the K-corona, together with polarized emission lines, to measure and correct instrument-induced polarized crosstalk. First we derive the Stokes parameters of the Thomson scattering of unpolarized light in an irreducible spherical tensor formalism. This allows forward synthesis of the Thomson-scattered signal for the more complex scenario that includes symmetry-breaking features in the incident radiation field, which could limit the accuracy of our proposed technique. For this, we make use of an advanced 3D radiative magnetohydrodynamic coronal model. Together with synthesized polarized signals in the Fe xiii 10746 Å emission line, we find that an ad hoc correction of telescope- and instrument-induced polarization crosstalk is possible under the assumption of a nondepolarizing optical system.
AbstractList Abstract Thomson-scattered photospheric light is the dominant constituent of the lower solar corona’s spectral continuum viewed off-limb at optical wavelengths. Known as the K-corona, it is also linearly polarized. We investigate the possibility of using the a priori polarized characteristics of the K-corona, together with polarized emission lines, to measure and correct instrument-induced polarized crosstalk. First we derive the Stokes parameters of the Thomson scattering of unpolarized light in an irreducible spherical tensor formalism. This allows forward synthesis of the Thomson-scattered signal for the more complex scenario that includes symmetry-breaking features in the incident radiation field, which could limit the accuracy of our proposed technique. For this, we make use of an advanced 3D radiative magnetohydrodynamic coronal model. Together with synthesized polarized signals in the Fe xiii 10746 Å emission line, we find that an ad hoc correction of telescope- and instrument-induced polarization crosstalk is possible under the assumption of a nondepolarizing optical system.
Thomson-scattered photospheric light is the dominant constituent of the lower solar corona’s spectral continuum viewed off-limb at optical wavelengths. Known as the K-corona, it is also linearly polarized. We investigate the possibility of using the a priori polarized characteristics of the K-corona, together with polarized emission lines, to measure and correct instrument-induced polarized crosstalk. First we derive the Stokes parameters of the Thomson scattering of unpolarized light in an irreducible spherical tensor formalism. This allows forward synthesis of the Thomson-scattered signal for the more complex scenario that includes symmetry-breaking features in the incident radiation field, which could limit the accuracy of our proposed technique. For this, we make use of an advanced 3D radiative magnetohydrodynamic coronal model. Together with synthesized polarized signals in the Fe xiii 10746 Å emission line, we find that an ad hoc correction of telescope- and instrument-induced polarization crosstalk is possible under the assumption of a nondepolarizing optical system.
Author Dima, Gabriel I.
Jaeggli, Sarah A.
Schad, Thomas A.
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  orcidid: 0000-0002-7451-9804
  surname: Schad
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  surname: Dima
  fullname: Dima, Gabriel I.
  organization: NOAA National Centers for Environmental Information , DSRC, 325 Broadway, Boulder, CO 80305, USA
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The Sun and the Heliosphere
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Snippet Abstract Thomson-scattered photospheric light is the dominant constituent of the lower solar corona’s spectral continuum viewed off-limb at optical...
Thomson-scattered photospheric light is the dominant constituent of the lower solar corona’s spectral continuum viewed off-limb at optical wavelengths. Known...
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crossref
iop
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Publisher
StartPage 53
SubjectTerms Astrophysics
Broken symmetry
Corona
Crosstalk
Emission
Emission lines
Emission measurements
Fluid flow
Incident radiation
Induced polarization
Linear polarization
Magnetohydrodynamics
Photosphere
Polarization
Radiation
Solar activity
Solar activity regions
Solar corona
Solar E corona
Solar K corona
Solar magnetic fields
Spectropolarimetry
Stokes parameters
Tensors
Thomson scattering
Wavelengths
Title Thomson Scattering above Solar Active Regions and an Ad Hoc Polarization Correction Method for the Emissive Corona
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Volume 933
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