Modeling the scattering polarization of the solar Ca I 4227 Å line with angle-dependent partial frequency redistribution

Janett, Gioele; Ballester, Ernest Alsina; Guerreiro, Nuno; Riva, Simone; Belluzzi, L.; Alemán, T. del Pino; Bueno, J. Trujillo

doi:10.1051/0004-6361/202141549

Cited by 13 publications

(18 citation statements)

References 52 publications

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“…The redistribution matrix is given by the sum of two terms, which characterize scattering processes that are coherent (R ii ) and completely incoherent (R iii ) in the atomic rest frame. In the observer's frame, we consider for computational simplicity the so-called angle-averaged approximation for R ii (Rees & Saliba 1982), which we expect to be suitable for modeling the wings of resonance lines (see Janett et al 2021). We also make the assumption that scattering is completely incoherent in the observer's frame for R iii .…”

Section: Formulation Of the Problemmentioning

confidence: 99%

The Potential of the Wavelength-integrated Scattering Polarization of the Hydrogen Lyα Line for Probing the Solar Chromosphere

Ballester

Belluzzi

Bueno

2023

ApJ

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The intensity and the linear scattering polarization profiles of the hydrogen Lyα line encode valuable information on the thermodynamic and magnetic structure of the upper layers of the solar chromosphere. The Chromospheric Lyman-Alpha Spectro-Polarimeter (CLASP) sounding rocket experiment provided unprecedented spectropolarimetric data of this line, as well as two-dimensional broadband images in intensity and linear polarization. We theoretically investigate the potential of the Lyα broadband polarimetric signals for probing the solar chromosphere and its magnetic fields. We analyze the synthetic Stokes profiles obtained from a series of radiative transfer (RT) calculations out of local thermodynamic equilibrium, considering semi-empirical one-dimensional models of the solar atmosphere. The wavelength-integrated linear polarization signal is found to be dominated by the contribution from the wings when considering a Gaussian weighting function with a FWHM that corresponds to the CLASP slit-jaw broadband filter. These broadband linear polarization signals are strongly sensitive to magnetic fields of strengths on the order of 50 G, via the action of magneto-optical (MO) effects, and are expected to encode information on the middle–upper chromosphere. The two-dimensional broadband intensity and linear polarization images observed by CLASP can be suitably mimicked using synthetic wavelength-integrated signals obtained considering atmospheric models and magnetic fields that are representative of solar regions with different levels of activity, provided that the impact of MO effects is taken into account. Despite the limitations of a one-dimensional RT modeling, this work illustrates the diagnostic potential of filter-polarimetric Lyα signals for probing the solar chromosphere and its magnetism.

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Section: Formulation Of the Problemmentioning

confidence: 99%

The Potential of the Wavelength-integrated Scattering Polarization of the Hydrogen Lyα Line for Probing the Solar Chromosphere

Ballester

Belluzzi

Bueno

2023

ApJ

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“…This quantity is proportional to the population of the lower level, which in turn depends on I in a nonlinear way through the statistical equilibrium equations. The redistribution matrix R only depends on local atmospheric quantites, therefore a suitable assumption to retrieve linearity with respect to I is to fix the coefficient k L a priori (see Belluzzi & Trujillo Bueno 2014;Alsina Ballester et al 2017;Janett et al 2021a). In this way, K is independent of I and ε linearly depends on it.…”

Section: Linearizationmentioning

confidence: 99%

“…We considered the Ca I line at 4227 Å, which is an ideal benchmark for new approaches to the modeling of scattering polarization including PRD effects and can be suitably modeled by considering a simple two-level atom (e.g., Faurobert-Scholl 1992;Sampoorna et al 2009;Supriya et al 2014;Alsina Ballester et al 2018;Janett et al 2021a). We considered the wavelength interval [λ min , λ max ] = [4220, 4234] Å, discretized with N ν = 99 nodes.…”

Section: Atomic and Atmospheric Modelsmentioning

confidence: 99%

“…We A&A 664, A197 (2022) recall that scattering polarization is intimately related to the geometrical properties (i.e., the anisotropy) of the radiation field that pumps the atoms. It therefore becomes apparent that a general angle-dependent treatment of PRD effects, without introducing simplifying assumptions, such as the angle-averaged one (e.g., Rees & Saliba 1982;Leenaarts et al 2012;Alsina Ballester et al 2017), can be essential for an accurate modeling (Janett et al 2021a). When angle-dependent PRD effects are accounted for, the numerical modeling of scattering polarization signals results in an extremely challenging computational problem with significant memory requirements.…”

Section: Introductionmentioning

confidence: 99%

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Numerical solutions to linear transfer problems of polarized radiation

Benedusi

Janett

Riva

et al. 2022

A&A

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Context. The polarization signals produced by the scattering of anistropic radiation in strong resonance lines encode important information about the elusive magnetic fields in the outer layers of the solar atmosphere. An accurate modeling of these signals is a very challenging problem from the computational point of view, in particular when partial frequency redistribution (PRD) effects in scattering processes are accounted for with a general angle-dependent treatment. Aims. We aim at solving the radiative transfer problem for polarized radiation in nonlocal thermodynamic equilibrium conditions, taking angle-dependent PRD effects into account. The problem is formulated for a two-level atomic model in the presence of arbitrary magnetic and bulk velocity fields. The polarization produced by scattering processes and the Zeeman effect is considered. Methods. The proposed solution strategy is based on an algebraic formulation of the problem and relies on a convenient physical assumption, which allows its linearization. We applied a nested matrix-free GMRES iterative method. Effective preconditioning is obtained in a multifidelity framework by considering the light-weight description of scattering processes in the limit of complete frequency redistribution (CRD). Results. Numerical experiments for a one-dimensional (1D) atmospheric model show near optimal strong and weak scaling of the proposed CRD-preconditioned GMRES method, which converges in few iterations, independently of the discretization parameters. A suitable parallelization strategy and high-performance computing tools lead to competitive run times, providing accurate solutions in a few minutes. Conclusions. The proposed solution strategy allows the fast systematic modeling of the scattering polarization signals of strong resonance lines, taking angle-dependent PRD effects into account together with the impact of arbitrary magnetic and bulk velocity fields. Almost optimal strong and weak scaling results suggest that this strategy is applicable to realistic 3D models. Moreover, the proposed strategy is general, and applications to more complex atomic models are possible.

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“…Appreciable errors in numerical calculations due to the angle-averaged approximation in R ii were reported in the past, both when considering semi-infinite and isothermal atmospheric models (Faurobert 1988;Sampoorna et al 2017) and when synthesizing strong resonance lines in semi-empirical atmospheric models (e.g., Janett et al 2021). The suitability of assuming CRD in the observer's reference frame for R iii in the polarized case was called into question by Bommier (1997), but more recent RT investigations by Sampoorna et al (2017) suggest that that the incurred error is minor when considering atmospheres with a large optical depth relative to the considered line.…”

Section: Equations Of the Problemmentioning

confidence: 99%

The polarization signals of the solar K I D lines and their magnetic sensitivity

Ballester

2022

A&A

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Aims. This work aims to identify the relevant physical processes in shaping the intensity and polarization patterns of the solar K i D lines through spectral syntheses, placing particular emphasis on the D 2 line. Methods. The theoretical Stokes profiles were obtained by numerically solving the radiative transfer problem for polarized radiation considering one-dimensional semi-empirical models of the solar atmosphere. The calculations account for scattering polarization, partial frequency redistribution (PRD) effects, hyperfine structure (HFS), J-and F-state interference, multiple isotopes, and magnetic fields of arbitrary strength and orientation.Results. The intensity and circular polarization profiles of both D lines can be suitably modeled while neglecting both J-state interference and HFS. The magnetograph formula can be applied to both lines, without including HFS, to estimate weak longitudinal magnetic fields in the lower chromosphere. By contrast, modeling the scattering polarization signal of the D lines requires the inclusion of HFS. The amplitude of the D 2 scattering polarization signal is strongly depolarized by HFS, but it remains measurable. A small yet appreciable error is incurred in the scattering polarization profile if PRD effects are not taken into account. Collisions during scattering processes have a clear depolarizing effect, although a quantitative analysis is left for a forthcoming publication. Finally, the D 2 scattering polarization signal is particularly sensitive to magnetic fields with strengths around 10 G and it strongly depends on their orientation. Despite this, its center-to-limb variation relative to the amplitude at the limb is largely insensitive to the field strength and orientation. Conclusions. These findings highlight the value of the K i D 2 line polarization for diagnostics of the solar magnetism, and show that the linear and circular polarization signals of this line are primarily sensitive to magnetic fields in the lower chromosphere and upper photosphere, respectively.

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Modeling the scattering polarization of the solar Ca I 4227 Å line with angle-dependent partial frequency redistribution

Cited by 13 publications

References 52 publications

The Potential of the Wavelength-integrated Scattering Polarization of the Hydrogen Lyα Line for Probing the Solar Chromosphere

The Potential of the Wavelength-integrated Scattering Polarization of the Hydrogen Lyα Line for Probing the Solar Chromosphere

Numerical solutions to linear transfer problems of polarized radiation

The polarization signals of the solar K I D lines and their magnetic sensitivity

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Modeling the scattering polarization of the solar Ca I 4227 Å line with angle-dependent partial frequency redistribution

Cited by 13 publications

References 52 publications

The Potential of the Wavelength-integrated Scattering Polarization of the Hydrogen Lyα Line for Probing the Solar Chromosphere

The Potential of the Wavelength-integrated Scattering Polarization of the Hydrogen Lyα Line for Probing the Solar Chromosphere

Numerical solutions to linear transfer problems of polarized radiation

The polarization signals of the solar K I D lines and their magnetic sensitivity

Contact Info

Product

Resources

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Modeling the scattering polarization of the solar Ca I 4227 Å line with angle-dependent partial frequency redistribution