Author name code: sampoorna
ADS astronomy entries on 2022-09-14
author:"Sampoorna, M."
------------------------------------------------------------------------
Title: Fast Iterative Techniques for Polarized Radiative Transfer
in Spherically Symmetric Moving Media
Authors: Megha, A.; Sampoorna, M.; Nagendra, K. N.; Anusha, L. S.;
Sankarasubramanian, K.
Bibcode: 2020ApJ...903....6M
Altcode:
For a more precise modeling of polarized spectral lines formed in
extended and expanding stellar atmospheres, the solution of the
radiative transfer equation for the Stokes vectors must be obtained
in a spherical geometry rather than in a planar geometry. In this
paper, we present the modern iterative techniques based on operator
perturbation to solve the spherically symmetric polarized radiative
transfer equation with velocity fields. We consider scattering on a
two-level atom and account for partial frequency redistribution. An
accurate numerical solution to such problems requires the use of
spatial grids with higher resolution. Consequently, Jacobi-based
methods lead to slower convergence rate. The convergence rate can be
improved by a factor of 2 or more when fast iterative schemes based
on Gauss-Seidel (GS) and successive overrelaxation (SOR) methods are
used over the Jacobi-based method. Here we present the Jacobi, GS,
and SOR iterative techniques for solving the abovementioned problem,
and discuss their convergence behavior.
Title: Importance of Angle-dependent Partial Frequency Redistribution
in Hyperfine Structure Transitions Under the Incomplete Paschen-Back
Effect Regime
Authors: Nagendra, K. N.; Sowmya, K.; Sampoorna, M.; Stenflo, J. O.;
Anusha, L. S.
Bibcode: 2020ApJ...898...49N
Altcode: 2020arXiv200704044N
Angle-frequency coupling in scattering of polarized light on atoms is
represented by the angle-dependent (AD) partial frequency redistribution
(PRD) matrices. There are several lines in the linearly polarized
solar spectrum, for which PRD combined with quantum interference
between hyperfine structure states play a significant role. Here we
present the solution of the polarized line transfer equation including
the AD-PRD matrix for scattering on a two-level atom with hyperfine
structure splitting and an unpolarized lower level. We account for
the effects of arbitrary magnetic fields (including the incomplete
Paschen-Back effect regime) and elastic collisions. For exploratory
purposes we consider a self-emitting isothermal planar atmosphere and
use atomic parameters that represent an isolated Na I D2
line. For this case we show that the AD-PRD effects are significant
for field strengths below about 30 G, but that the computationally
much less demanding approximation of angle-averaged PRD may be used
for stronger fields.
Title: Resonance Line Polarization in Spherically Symmetric Moving
Media: a Parametric Study
Authors: Megha, A.; Sampoorna, M.; Nagendra, K. N.; Anusha, L. S.;
Sankarasubramanian, K.
Bibcode: 2020arXiv200106201M
Altcode:
In the present paper we consider the problem of resonance
line polarization formed in the spherically symmetric expanding
atmospheres. For the solution of the concerned polarized transfer
equation we use the comoving frame formulation, and apply the
Accelerated Lambda Iteration (ALI) method. We restrict ourselves to
the non-relativistic regime of velocities wherein mainly Doppler shift
effects are significant. For our studies, we consider the scattering
on a two-level atom, including the effects of partial frequency
redistribution (PFR). We present the dependence of linearly polarized
profiles on different atmospheric and atomic parameters.
Title: Polarized Line Formation in Arbitrary Strength Magnetic Fields:
The Case of a Two-level Atom with Hyperfine Structure Splitting
Authors: Sampoorna, M.; Nagendra, K. N.; Sowmya, K.; Stenflo, J. O.;
Anusha, L. S.
Bibcode: 2019ApJ...883..188S
Altcode: 2019arXiv191010913S
Quantum interference effects, together with partial frequency
redistribution (PFR) in line scattering, produce subtle signatures in
the so-called Second Solar Spectrum (the linearly polarized spectrum of
the Sun). These signatures are modified in the presence of arbitrary
strength magnetic fields via the Hanle, Zeeman, and Paschen-Back
effects. In the present paper we solve the problem of polarized line
formation in a magnetized atmosphere taking into account scattering in a
two-level atom with hyperfine structure splitting together with PFR. To
this end we incorporate the collisionless PFR matrix derived in Sowmya
et al. in the polarized transfer equation. We apply the scattering
expansion method to solve this transfer equation. We study the combined
effects of PFR and the Paschen-Back effect on polarized line profiles
formed in an isothermal one-dimensional planar atmosphere. For this
purpose, we consider the cases of D2 lines of Li I and Na I.
Title: Resonance Line Polarization in Spherically Symmetric Moving
Media: a Parametric Study.
Authors: Megha, A.; Sampoorna, M.; Nagendra, K. N.; Anusha, L. S.;
Sankarasubramanian, K.
Bibcode: 2019spw..confE..14M
Altcode:
No abstract at ADS
Title: Polarized Line Transfer in the Incomplete Paschen-Back Effect
Regime with Angle-dependent Partial Frequency Redistribution.
Authors: Nagendra, K. N.; Sowmya, K.; Sampoorna, M.; Stenflo, J. O.;
Anusha, L. S.
Bibcode: 2019spw..confE..13N
Altcode:
No abstract at ADS
Title: Solution of Polarized Radiative Transfer Equation with
Cross-redistribution.
Authors: Nagendra, K. N.; Sampoorna, M.
Bibcode: 2019spw..confE...1N
Altcode:
No abstract at ADS
Title: Effects of Angle-Dependent Partial Frequency Redistribution
on Polarized Line Profiles
Authors: Sampoorna, M.; Nagendra, K. N.; Frisch, H.; Stenflo, J. O.
Bibcode: 2019ASPC..519..109S
Altcode:
Scattering of the solar limb-darkened radiation field on atoms and
molecules produces linearly polarized spectrum of the Sun (Second Solar
Spectrum). Partial frequency redistribution (PFR) plays a fundamental
role in shaping the wings of linearly polarized profiles of strong
resonance lines. Here we present the effects of the angle-dependent
(AD) PFR on resonance polarization both in the presence and absence
of magnetic fields. We consider scattering on a two-level atom with
unpolarized lower level, and a one-dimensional isothermal atmosphere.
Title: Polarized Line Formation in Spherically Symmetric Expanding
Atmospheres
Authors: Megha, A.; Sampoorna, M.; Nagendra, K. N.; Anusha, L. S.;
Sankarasubramanian, K.
Bibcode: 2019ASPC..519...27M
Altcode:
We consider the problem of polarized line formation in the spherically
symmetric expanding atmospheres. The velocity fields in line forming
regions produce Doppler shift, aberration of photons and also gives
rise to advection. These in turn can modify the amplitudes and
shapes of the emergent Stokes profiles. However, here we consider
only non-relativistic regime, wherein mainly Doppler shift effects
are significant. Thus only Doppler shift terms are considered in
the polarized transfer equation. For the solution of the concerned
polarized transfer equation we use the comoving frame formulation,
and apply the Accelerated Lambda Iteration (ALI) method. We present the
results by considering the scattering on a two-level atom, including the
effects of partial frequency redistribution (PFR). The polarized line
profiles are shown for few velocity laws, representative of expanding
spherical atmospheres. It is shown that the degree of polarization in
the lines depends sensitively on the extendedness R of the spherical
atmosphere. We also present a comparison of polarized profiles computed
under complete frequency redistribution (CFR) and PFR in the case of
static as well as expanding atmospheres.
Title: Polarized Line Formation with Incomplete Paschen-Back Effect
and Partial Frequency Redistribution
Authors: Sampoorna, M.; Nagendra, K. N.; Sowmya, K.; Stenflo, J. O.;
Anusha, L. S.
Bibcode: 2019ASPC..519..113S
Altcode:
Quantum interference between the hyperfine structure states is
known to depolarize the cores of some of the lines in the linearly
polarized spectrum of the Sun (the Second Solar Spectrum). The
presence of external magnetic fields in the line forming regions
modify these signatures through the Hanle, Zeeman, and incomplete/
complete Paschen-Back effects (PBE), depending on the strength of the
magnetic field. In an earlier paper, Sowmya et al. (2014) derived the
relevant collisionless partial frequency redistribution (PFR) matrix
for scattering on a two-level atom with hyperfine structure splitting
(HFS) and in the presence of arbitrary strength magnetic fields
(including the PBE regime). In the present paper we solve the problem
of polarized line transfer in a magnetized atmosphere, including this
PFR matrix. For this purpose, we apply a scattering expansion method
which is based on orders of scattering approach. We present the results
on the combined effects of PBE and PFR on the polarized line profiles
using the atomic parameters relevant to the Na I D2 line.
Title: Polarized Line Formation in Spherically Symmetric Atmospheres
with Velocity Fields
Authors: Megha, A.; Sampoorna, M.; Nagendra, K. N.; Anusha, L. S.;
Sankarasubramanian, K.
Bibcode: 2019ApJ...879...48M
Altcode:
The plane-parallel approximation of the stellar atmospheres cannot
be applied to model the formation of optically thick lines formed in
extended atmospheres. To a good approximation these atmospheres can be
represented by a spherically symmetric medium. Such extended stellar
atmospheres are dynamic, in general, due to the systematic motions
present in their layers. Macroscopic velocity fields in the spectral
line forming regions produce Doppler shift, aberration of photons,
and also give rise to advection. All of these effects can modify
the amplitudes and shapes of the emergent Stokes profiles. In the
present paper we consider the problem of polarized line formation
in spherically symmetric media, in the presence of velocity
fields. Solving the radiative transfer problem in the observer’s
frame is a straightforward approach to handle the presence of velocity
fields. This method, however, becomes computationally prohibitive when
large velocity fields are considered, particularly in the case of the
line formation with partial frequency redistribution (PFR). In this
paper we present a polarized comoving frame method to solve the problem
at hand. We consider nonrelativistic radial velocity fields, thereby
accounting only for Doppler shift effects and neglecting advection
and aberration of photons. We study the effects of extendedness,
velocity fields, and PFR on the polarized line profiles formed in
highly extended atmospheres.
Title: Comoving Frame Method for Polarized PRD Line Transfer with
Velocity Fields
Authors: Sampoorna, M.; Nagendra, K. N.
Bibcode: 2019ASPC..526..153S
Altcode:
The solution of the transfer equation in moving atmospheres is a
classical problem. While the low-velocity regime can be handled in
a simpler manner using the observer's frame method, the regime of
high-velocity requires the comoving frame technique to be applied. We
show that even in the low-velocity regime (like that prevailing in the
solar atmosphere) we require the comoving frame method when linear
polarization together with partial frequency redistribution (PRD)
in line scattering is considered. This situation arises because of
the numerical difficulties that we encounter in the observer's frame
method, namely, a heavy demand on the angle, frequency, and depth
grids when we consider polarized line formation with PRD and velocity
fields. These difficulties can be overcome by applying the comoving
frame technique. Here we present the details of this technique and
its applications to solar-like conditions.
Title: Polarized Scattering Matrix for Magnetic Dipole Transitions
Authors: Megha, A.; Sampoorna, M.; Nagendra, K. N.; Sankarasubramanian,
K.
Bibcode: 2019ASPC..526..207M
Altcode:
Forbidden emission lines, produced by magnetic dipole (M1) transitions,
are difficult to observe in the laboratory, but naturally arise in the
highly ionized atoms present in the solar corona. The polarization of
these lines is the result of anisotropic excitation processes. The
polarization measurement of forbidden emission lines is the most
direct method of determining the magnetic field direction in the solar
corona. Here we consider the general case of M1 transitions in the
presence of magnetic fields of arbitrary strength. In particular,
we derive the scattering matrix for the M1 transitions using the
classical magnetic dipole oscillator model of Casini & Lin (2002)
and applying the scattering matrix approach of Stenflo (1998). The
derived scattering matrix covers, in a continuous way, saturated Hanle,
intermediate Hanle-Zeeman, and Zeeman regimes.
Title: Partial Frequency Redistribution Theory with Paschen-Back
Effect: Application to Li I 6708 Å Lines
Authors: Sowmya, K.; Nagendra, K. N.; Sampoorna, M.; Stenflo, J. O.
Bibcode: 2019ASPC..526...43S
Altcode:
The diagnostically important Li I D lines in the Second Solar Spectrum
are governed by the quantum interference processes that take place among
the magnetic substates belonging to different fine (J) and hyperfine (F)
structure states. This interference gets modified in the presence of
a magnetic field. The signatures of this interference in polarization
contain information on the nature of the vector magnetic field in
the solar atmosphere. With this motivation, we apply the polarized
redistribution matrix including Paschen-Back effect, derived based
on the Kramers-Heisenberg scattering matrix approach, to model the
polarization profiles of the Li lines observed in the quiet Sun. We
make use of the last scattering approximation which is based on the
concept that the polarization of the emergent radiation is generated
in the last scattering event, before the radiation escapes from the
atmosphere. We present a comparison of the quiet Sun observations of
the linear polarization profiles of Li I 6708 Å line system with the
theoretical profiles computed using our simple modeling approach. We
also present theoretical Stokes profiles in the Paschen-Back regime
of magnetic fields and compare them with the single scattered profiles.
Title: Effects of Lower-Level Polarization and Partial Frequency
Redistribution on Stokes Profiles
Authors: Supriya, H. D.; Nagendra, K. N.; Sampoorna, M.; Stenflo,
J. O.; Ravindra, B.
Bibcode: 2019ASPC..526...61S
Altcode:
The theory of polarized radiative transfer including the effects of
partial frequency redistribution (PRD) for a two-level and two-term atom
has been formulated in the scattering matrix approach. However there
exist several enigmatic features in the Second Solar Spectrum which
cannot be explained on the basis of said approach. The reason for this
lies in the approximations made in this approach. One such approximation
is the assumption that the lower level of the atom involved in the
scattering process is unpolarized. There are alternative approaches
based on the density matrix formalism to relax this assumption. It has
been shown that the inclusion of the polarization of all the atomic
levels involved in the scattering process is important. In our recent
studies, the collisionless redistribution matrix including the effects
of both PRD and lower-level polarization (LLP) was derived starting
from the Kramers-Heisenberg scattering formulation. We proposed a
simple numerical technique namely, the correction method, to solve
the problem of polarized radiative transfer with PRD and LLP. Here
we apply this technique to different atomic systems and discuss the
effects of PRD and LLP on the emergent Stokes profiles.
Title: Coronal magnetic field measurements using forbidden emission
lines
Authors: Megha, A.; Sampoorna, M.; Nagendra, K. N.; Sankarasubramanian,
K.
Bibcode: 2018IAUS..340...61M
Altcode:
The polarization measurement of coronal forbidden emission lines is the
most promising method of determining the direction of magnetic fields
in the corona. A classical theory for the forbidden lines was presented
in Megha et al. (2017) for the case of arbitrary strength magnetic
fields. Here we apply that theoretical formalism to study the effect
of density distributions, magnetic field configurations, and velocity
fields on the Stokes profiles formed in corona. For illustrations we use
the atomic parameters of the [Fe xiii] 10747 Å coronal forbidden line.
Title: Polarized Line Formation in Arbitrary Strength Magnetic Fields
Angle-averaged and Angle-dependent Partial Frequency Redistribution
Authors: Sampoorna, M.; Nagendra, K. N.; Stenflo, J. O.
Bibcode: 2017ApJ...844...97S
Altcode:
Magnetic fields in the solar atmosphere leave their fingerprints in the
polarized spectrum of the Sun via the Hanle and Zeeman effects. While
the Hanle and Zeeman effects dominate, respectively, in the weak
and strong field regimes, both these effects jointly operate in the
intermediate field strength regime. Therefore, it is necessary to
solve the polarized line transfer equation, including the combined
influence of Hanle and Zeeman effects. Furthermore, it is required
to take into account the effects of partial frequency redistribution
(PRD) in scattering when dealing with strong chromospheric lines with
broad damping wings. In this paper, we present a numerical method to
solve the problem of polarized PRD line formation in magnetic fields
of arbitrary strength and orientation. This numerical method is based
on the concept of operator perturbation. For our studies, we consider
a two-level atom model without hyperfine structure and lower-level
polarization. We compare the PRD idealization of angle-averaged
Hanle-Zeeman redistribution matrices with the full treatment of
angle-dependent PRD, to indicate when the idealized treatment is
inadequate and what kind of polarization effects are specific to
angle-dependent PRD. Because the angle-dependent treatment is presently
computationally prohibitive when applied to realistic model atmospheres,
we present the computed emergent Stokes profiles for a range of magnetic
fields, with the assumption of an isothermal one-dimensional medium.
Title: Hanle-Zeeman Scattering Matrix for Magnetic Dipole Transitions
Authors: Megha, A.; Sampoorna, M.; Nagendra, K. N.; Sankarasubramanian,
K.
Bibcode: 2017ApJ...841..129M
Altcode:
The polarization of the light that is scattered by the coronal ions is
influenced by the anisotropic illumination from the photosphere and
the magnetic field structuring in the solar corona. The properties
of the coronal magnetic fields can be well studied by understanding
the polarization properties of coronal forbidden emission lines that
arise from magnetic dipole (M1) transitions in the highly ionized
atoms that are present in the corona. We present the classical
scattering theory of the forbidden lines for a more general case of
arbitrary-strength magnetic fields. We derive the scattering matrix
for M1 transitions using the classical magnetic dipole model of Casini
& Lin and applying the scattering matrix approach of Stenflo. We
consider a two-level atom model and neglect collisional effects. The
scattering matrix so derived is used to study the Stokes profiles
formed in coronal conditions in those regions where the radiative
excitations dominate collisional excitations. To this end, we take
into account the integration over a cone of an unpolarized radiation
from the solar disk incident on the scattering atoms. Furthermore,
we also integrate along the line of sight to calculate the emerging
polarized line profiles. We consider radial and dipole magnetic field
configurations and spherically symmetric density distributions. For
our studies we adopt the atomic parameters corresponding to the [Fe
xiii] 10747 Å coronal forbidden line. We also discuss the nature of
the scattering matrix for M1 transitions and compare it with that for
the electric dipole (E1) transitions.
Title: Importance of Cross-redistribution in Scattering Polarization
of Spectral Lines: The Cases of 3P-3S Triplets
of Mg I and Ca I
Authors: Sampoorna, M.; Nagendra, K. N.
Bibcode: 2017ApJ...838...95S
Altcode:
Scattering on a multi-level atomic system has dominant contributions
from resonance and Raman scattering. While initial and final
levels are the same for resonance scattering, they are different
for Raman scattering. The frequency redistribution for resonance
scattering is described by the usual partial frequency redistribution
functions of Hummer, while that for Raman scattering is described
by cross-redistribution (XRD) function. In the present paper, we
investigate the importance of XRD on linear polarization profiles
of 3P-3S triplets of Mg I and Ca I formed in
an isothermal one-dimensional atmosphere. We show that XRD produces
significant effects on the linear polarization profiles when the
wavelength separations between the line components of the multiplet
are small, like in the cases of Mg I b and Ca I triplets.
Title: Polarized Line Formation in Non-monotonic Velocity Fields
Authors: Sampoorna, M.; Nagendra, K. N.
Bibcode: 2016ApJ...833...32S
Altcode:
For a correct interpretation of the observed spectro-polarimetric
data from astrophysical objects such as the Sun, it is necessary
to solve the polarized line transfer problems taking into account a
realistic temperature structure, the dynamical state of the atmosphere,
a realistic scattering mechanism (namely, the partial frequency
redistribution—PRD), and the magnetic fields. In a recent paper,
we studied the effects of monotonic vertical velocity fields on
linearly polarized line profiles formed in isothermal atmospheres
with and without magnetic fields. However, in general the velocity
fields that prevail in dynamical atmospheres of astrophysical objects
are non-monotonic. Stellar atmospheres with shocks, multi-component
supernova atmospheres, and various kinds of wave motions in solar and
stellar atmospheres are examples of non-monotonic velocity fields. Here
we present studies on the effect of non-relativistic non-monotonic
vertical velocity fields on the linearly polarized line profiles formed
in semi-empirical atmospheres. We consider a two-level atom model and
PRD scattering mechanism. We solve the polarized transfer equation in
the comoving frame (CMF) of the fluid using a polarized accelerated
lambda iteration method that has been appropriately modified for the
problem at hand. We present numerical tests to validate the CMF method
and also discuss the accuracy and numerical instabilities associated
with it.
Title: Polarized Line Formation with Lower-level Polarization and
Partial Frequency Redistribution
Authors: Supriya, H. D.; Sampoorna, M.; Nagendra, K. N.; Stenflo,
J. O.; Ravindra, B.
Bibcode: 2016ApJ...828...84S
Altcode:
In the well-established theories of polarized line formation with
partial frequency redistribution (PRD) for a two-level and two-term
atom, it is generally assumed that the lower level of the scattering
transition is unpolarized. However, the existence of unexplained
spectral features in some lines of the Second Solar Spectrum points
toward a need to relax this assumption. There exists a density matrix
theory that accounts for the polarization of all the atomic levels,
but it is based on the flat-spectrum approximation (corresponding to
complete frequency redistribution). In the present paper we propose a
numerical algorithm to solve the problem of polarized line formation
in magnetized media, which includes both the effects of PRD and the
lower level polarization (LLP) for a two-level atom. First we derive a
collisionless redistribution matrix that includes the combined effects
of the PRD and the LLP. We then solve the relevant transfer equation
using a two-stage approach. For illustration purposes, we consider
two case studies in the non-magnetic regime, namely, the J
a = 1, J b = 0 and J a = J b
= 1, where J a and J b represent the
total angular momentum quantum numbers of the lower and upper states,
respectively. Our studies show that the effects of LLP are significant
only in the line core. This leads us to propose a simplified numerical
approach to solve the concerned radiative transfer problem.
Title: Polarized Scattering of Light for Arbitrary Magnetic Fields
with Level-crossings from the Combination of Hyperfine and Fine
Structure Splittings
Authors: Sowmya, K.; Nagendra, K. N.; Sampoorna, M.; Stenflo, J. O.
Bibcode: 2015ApJ...814..127S
Altcode: 2015arXiv151207736S
Interference between magnetic substates of the hyperfine structure
states belonging to different fine structure states of the same term
influences the polarization for some of the diagnostically important
lines of the Sun's spectrum, like the sodium and lithium doublets. The
polarization signatures of this combined interference contain
information on the properties of the solar magnetic fields. Motivated
by this, in the present paper, we study the problem of polarized
scattering on a two-term atom with hyperfine structure by accounting
for the partial redistribution in the photon frequencies arising due
to the Doppler motions of the atoms. We consider the scattering atoms
to be under the influence of a magnetic field of arbitrary strength
and develop a formalism based on the Kramers-Heisenberg approach to
calculate the scattering cross section for this process. We explore the
rich polarization effects that arise from various level-crossings in
the Paschen-Back regime in a single scattering case using the lithium
atomic system as a concrete example that is relevant to the Sun.
Title: Paschen-Back effect involving atomic fine and hyperfine
structure states
Authors: Sowmya, K.; Nagendra, K. N.; Sampoorna, M.; Stenflo, J. O.
Bibcode: 2015IAUS..305..154S
Altcode:
The linear polarization in spectral lines produced by coherent
scattering is significantly modified by the quantum interference between
the atomic states in the presence of a magnetic field. When magnetic
fields produce a splitting which is of the order of or greater than the
fine or hyperfine structure splittings, we enter the Paschen-Back effect
(PBE) regime, in which the magnetic field dependence of the Zeeman
splittings and transition amplitudes becomes non-linear. In general,
PBE occurs for sufficiently strong fields when the fine structure
states are involved and for weak fields in the case of hyperfine
structure states. In this work, we apply the recently developed theory
of PBE in the atomic fine and hyperfine structure states including the
effects of partial frequency redistribution to the case of Li i 6708
Å doublet. We explore the signatures of PBE in a single scattering
event and their applicability to the solar magnetic field diagnostics.
Title: A revisit to model the Cr i triplet at 5204-5208 Å and the
Ba ii D2 line at 4554 Å in the Second Solar Spectrum
Authors: Smitha, H. N.; Nagendra, K. N.; Stenflo, J. O.; Bianda, M.;
Sampoorna, M.; Ramelli, R.
Bibcode: 2015IAUS..305..372S
Altcode:
In our previous attempt to model the Stokes profiles of the Cr i triplet
at 5204-5208 Å and the Ba ii D2 at 4554 Å, we found it
necessary to slightly modify the standard FAL model atmospheres to fit
the observed polarization profiles. In the case of Cr i triplet, this
modification was done to reduce the theoretical continuum polarization,
and in the case of Ba ii D2, it was needed to reproduce the
central peak in Q/I. In this work, we revisit both these cases using
different standard model atmospheres whose temperature structures
closely resemble those of the modified FAL models, and explore the
possibility of synthesizing the line profiles without the need for
small modifications of the model atmosphere.
Title: Polarized Line Formation in Moving Atmospheres with Partial
Frequency Redistribution and a Weak Magnetic Field
Authors: Sampoorna, M.; Nagendra, K. N.
Bibcode: 2015ApJ...812...28S
Altcode:
The dynamical state of the solar and stellar atmospheres depends
on the macroscopic velocity fields prevailing within them. The
presence of such velocity fields in the line formation regions
strongly affects the polarized radiation field emerging from these
atmospheres. Thus it becomes necessary to solve the radiative transfer
equation for polarized lines in moving atmospheres. Solutions based
on the “observer’s frame method” are computationally expensive
to obtain, especially when partial frequency redistribution (PRD)
in line scattering and large-amplitude velocity fields are taken into
account. In this paper we present an efficient alternative method of
solution, namely, the comoving frame technique, to solve the polarized
PRD line formation problems in the presence of velocity fields. We
consider one-dimensional planar isothermal atmospheres with vertical
velocity fields. We present a study of the effect of velocity fields
on the emergent linear polarization profiles formed in optically
thick moving atmospheres. We show that the comoving frame method is
far superior when compared to the observer’s frame method in terms
of the computational speed and memory requirements.
Title: Partial Redistribution Effects on Polarized Lines Formed in
Moving Media in the Presence of a Weak Magnetic Field
Authors: Sampoorna, M.; Nagendra, K. N.
Bibcode: 2015IAUS..305..387S
Altcode:
Macroscopic velocity fields in stellar atmospheres significantly
affect the shapes of the emergent Stokes profiles. The inextricable
coupling between the angle and frequency variables becomes more
complex in a moving medium when compared to a static medium. In this
paper we consider both complete frequency redistribution (CRD) and
partial frequency redistribution (PRD) in the line scattering of a
two-level atom in the presence of an external weak magnetic field. For
simplicity we consider empirical velocity laws to represent motion of
the atmospheric layers. We present emergent Stokes profiles computed
with CRD, angle-averaged PRD, and angle-dependent PRD. We show that
angle-dependent PRD effects are important both in non-magnetic and
magnetized scattering when vertical velocity gradients are present
in the atmosphere. The results are presented for simple atmospheric
models. They are expected to be of relevance to polarized line formation
in slowly expanding chromospheric layers.
Title: Electron Scattering Redistribution Effect on Atomic Line
Polarization
Authors: Supriya, H. D.; Nagendra, K. N.; Ravindra, B.; Sampoorna, M.
Bibcode: 2014ASPC..489..117S
Altcode:
The scattering of line photons on free electrons modifies the
polarization of the atomic spectral lines. Hence it is important to
treat scattering by electrons as a redistribution process and to study
in detail its effect on line formation. The numerically difficult
problem of evaluation and the use of angle-dependent atomic and
electron scattering redistribution functions in the line transfer
equation is considered. Two numerical methods, namely approximate
lambda iteration and scattering expansion method, are used to solve
the relevant polarized transfer problem. A study of the polarized
line formation in a standard two-level atom picture including an exact
treatment of electron scattering redistribution shows the importance
of the latter in the analysis of polarized line profiles emitted by
solar and stellar atmospheres. The effect of electron scattering turns
out to be extremely important in the interpretation of very far wing
line polarization of solar and stellar spectral lines.
Title: Polarized Line Formation with Angle-Dependent Partial Frequency
Redistribution
Authors: Sampoorna, M.
Bibcode: 2014ASPC..489..197S
Altcode:
The linear polarization of spectral lines seen in the solar limb
observations is created by the scattering of the anisotropic radiation
field by atoms and molecules. The partial frequency redistribution (PRD)
effects in line scattering are necessary ingredients for interpreting
the linear polarization observed in strong resonance lines. This
polarization is sensitive to the form of the PRD function used in
the polarized line transfer equation. The use of angle-averaged PRD
function is quite common in the literature on polarized transfer, as
it greatly reduces the computing efforts. In this paper we present our
recent work on the importance of the angle-dependent PRD in polarized
line transfer. First we present a brief historical background on
polarized transfer with angle-dependent PRD. To simplify the numerical
work needed to handle angle-dependent PRD function a Stokes vector
decomposition technique was developed by Frisch (2009, 2010). After
briefly recalling this technique, we present two numerical methods
developed to solve the polarized line transfer with angle-dependent
PRD. These are (1) polarized accelerated lambda iteration method and
(2) the scattering expansion method. Through illustrative examples,
we show that while angle-dependent effects are somewhat less important
for scattering polarization in the absence of magnetic fields, they
play an important role in the presence of a weak magnetic field.
Title: Solar Polarization 7
Authors: Nagendra, K. N.; Stenflo, J. O.; Qu, Z. Q.; Sampoorna, M.
Bibcode: 2014ASPC..489.....N
Altcode:
No abstract at ADS
Title: The Role of Quantum Interference and Partial Redistribution
in the Solar Ba <font size=2>II D2 4554 Å Line
Authors: Smitha, H. N.; Nagendra, K. N.; Stenflo, J. O.; Sampoorna, M.
Bibcode: 2014ASPC..489..213S
Altcode: 2014arXiv1409.0465S
The Ba <font size=2>II D2 line at 4554 Å is a good
example, where the F-state interference effects due to the odd isotopes
produce polarization profiles, which are very different from those
of the even isotopes that do not exhibit F-state interference. It is
therefore necessary to account for the contributions from the different
isotopes to understand the observed linear polarization profiles of
this line. In this paper we present radiative transfer modeling with
partial frequency redistribution, which is shown to be essential to
model this line. This is because complete frequency redistribution
cannot reproduce the observed wing polarization. We present the observed
and computed Q/I profiles at different limb distances. The theoretical
profiles strongly depend on limb distance (μ) and the model atmosphere
which fits the limb observations fails at other μ positions.
Title: Intrinsically Polarized Blend Lines
Authors: Sowmya, K.; Nagendra, K. N.; Sampoorna, M.
Bibcode: 2014ASPC..489..125S
Altcode:
The Second Solar Spectrum formed by coherent scattering processes in
the Sun, is highly structured. It is characterized by numerous blend
lines, both intrinsically polarizing and depolarizing, superposed on the
background continuum. These blend lines play an important role in the
interpretation of the Second Solar Spectrum. Since blend lines affect
the shapes of the neighboring spectral lines they have to be treated in
a sophisticated manner in order to efficiently model a given spectral
line of interest. The depolarizing blend lines - mostly considered to be
formed under LTE conditions - depolarize the background continuum and
thereby affect the absolute scale of the polarization measurement. An
understanding of the influence of the blend lines leads to a proper
determination of the zero-point of the polarization scale. With this
motivation we extend a previously developed framework to include many
blend lines formed under NLTE conditions, in the radiative transfer
equation. The results are shown for the particular case of two blend
lines situated on either side of the main spectral line.
Title: Polarized Light Scattering with the Paschen-Back Effect,
Level-crossing of Fine Structure States, and Partial Frequency
Redistribution
Authors: Sowmya, K.; Nagendra, K. N.; Sampoorna, M.; Stenflo, J. O.
Bibcode: 2014ApJ...793...71S
Altcode: 2014arXiv1407.5457S
The quantum interference between the fine structure states of an atom
modifies the shapes of the emergent Stokes profiles in the second solar
spectrum. This phenomenon has been studied in great detail both in the
presence and absence of magnetic fields. By assuming a flat-spectrum
for the incident radiation, the signatures of this effect have been
explored for arbitrary field strengths. Even though the theory which
takes into account the frequency dependence of the incident radiation
is well developed, it is restricted to the regime in which the magnetic
splitting is much smaller than the fine structure splitting. In the
present paper, we carry out a generalization of our scattering matrix
formalism including the effects of partial frequency redistribution
for arbitrary magnetic fields. We test the formalism using available
benchmarks for special cases. In particular, we apply it to the Li
I 6708 Å D1 and D2 line system, for which
observable effects from the Paschen-Back regime are expected in the
Sun's spectrum.
Title: Polarized Scattering with Paschen-Back Effect, Hyperfine
Structure, and Partial Frequency Redistribution in Magnetized
Stellar Atmospheres
Authors: Sowmya, K.; Nagendra, K. N.; Stenflo, J. O.; Sampoorna, M.
Bibcode: 2014ApJ...786..150S
Altcode: 2015arXiv151207731S
F-state interference significantly modifies the polarization
produced by scattering processes in the solar atmosphere. Its
signature in the emergent Stokes spectrum in the absence of magnetic
fields is depolarization in the line core. In the present paper,
we derive the partial frequency redistribution (PRD) matrix that
includes interference between the upper hyperfine structure states
of a two-level atom in the presence of magnetic fields of arbitrary
strengths. The theory is applied to the Na I D2 line that
is produced by the transition between the lower J = 1/2 and upper J =
3/2 states which split into F states because of the coupling with the
nuclear spin Is = 3/2. The properties of the PRD matrix for
the single-scattering case is explored, in particular, the effects of
the magnetic field in the Paschen-Back regime and their usefulness as
a tool for the diagnostics of solar magnetic fields.
Title: Line-interlocking Effects on Polarization in Spectral Lines
by Rayleigh and Raman Scattering
Authors: Sampoorna, M.; Nagendra, K. N.; Stenflo, J. O.
Bibcode: 2013ApJ...770...92S
Altcode:
The polarized spectrum of the Sun and stars is formed from the
scattering of anisotropic radiation on atoms. Interpretation of
this spectrum requires the solution of polarized line transfer in
multilevel atomic systems. While sophisticated quantum theories of
polarized line formation in multilevel atomic systems exist, they are
limited by the approximation of complete frequency redistribution
in scattering. The partial frequency redistribution (PRD) in line
scattering is a necessary component in modeling the polarized spectra
of strong lines. The polarized PRD line scattering theories developed so
far confine themselves to a two-level or a two-term atom model. In this
paper, we present a heuristic approach to the problem of polarized line
formation in multilevel atoms taking into account the effects of PRD
and a weak magnetic field. Starting from the unpolarized PRD multilevel
atom approach of Hubeny et al., we incorporate the polarization state
of the radiation field. However, the lower level polarization is
neglected. Two iterative methods of solving the polarized PRD line
transfer in multilevel atoms are also presented. Taking the example
of a five-level Ca II atom model, we present illustrative results for
an isothermal one-dimensional model atmosphere.
Title: Modeling the Quantum Interference Signatures of the Ba II
D2 4554 Å Line in the Second Solar Spectrum
Authors: Smitha, H. N.; Nagendra, K. N.; Stenflo, J. O.; Sampoorna, M.
Bibcode: 2013ApJ...768..163S
Altcode: 2013arXiv1303.7304S
Quantum interference effects play a vital role in shaping the linear
polarization profiles of solar spectral lines. The Ba II D2
line at 4554 Å is a prominent example, where the F-state interference
effects due to the odd isotopes produce polarization profiles,
which are very different from those of the even isotopes that have
no F-state interference. It is therefore necessary to account for the
contributions from the different isotopes to understand the observed
linear polarization profiles of this line. Here we do radiative
transfer modeling with partial frequency redistribution (PRD) of such
observations while accounting for the interference effects and isotope
composition. The Ba II D2 polarization profile is found
to be strongly governed by the PRD mechanism. We show how a full PRD
treatment succeeds in reproducing the observations, while complete
frequency redistribution alone fails to produce polarization profiles
that have any resemblance to the observed ones. However, we also find
that the line center polarization is sensitive to the temperature
structure of the model atmosphere. To obtain a good fit to the line
center peak of the observed Stokes Q/I profile, a small modification
of the FALX model atmosphere is needed, by lowering the temperature
in the line-forming layers. Because of the pronounced temperature
sensitivity of the Ba II D2 line it may not be a suitable
tool for Hanle magnetic-field diagnostics of the solar chromosphere,
because there is currently no straightforward way to separate the
temperature and magnetic-field effects from each other.
Title: An efficient decomposition technique to solve angle-dependent
Hanle scattering problems
Authors: Supriya, H. D.; Sampoorna, M.; Nagendra, K. N.; Ravindra,
B.; Anusha, L. S.
Bibcode: 2013JQSRT.119...67S
Altcode: 2013arXiv1304.5321S
Hanle scattering is an important diagnostic tool to study weak solar
magnetic fields. Partial frequency redistribution (PRD) is necessary
to interpret the linear polarization observed in strong resonance
lines. Usually angle-averaged PRD functions are used to analyze
linear polarization. However, it is established that angle-dependent
PRD functions are often necessary to interpret polarization profiles
formed in the presence of weak magnetic fields. Our aim is to present
an efficient decomposition technique, and the numerical method to solve
the concerned angle-dependent line transfer problem. Together with the
standard Stokes decomposition technique, we employ Fourier expansion
over the outgoing azimuth angle to express in a more convenient form,
the angle-dependent PRD function for the Hanle effect. It allows the
use of angle-dependent frequency domains of Bommier to solve the Hanle
transfer problem. Such an approach is self-consistent and accurate
compared to a recent approach where angle-averaged frequency domains
were used to solve the same problem. We show that it is necessary to
incorporate angle-dependent frequency domains instead of angle-averaged
frequency domains to solve the Hanle transfer problem accurately,
especially for the Stokes U parameter. The importance of using
angle-dependent domains has been highlighted by taking the example
of Hanle effect in the case of line transfer with vertical magnetic
fields in a slab atmosphere. We have also studied the case of polarized
line formation when micro-turbulent magnetic fields are present. The
difference between angle-averaged and angle-dependent solutions is
enhanced by the presence of micro-turbulent fields.
Title: Quantum interference with angle-dependent partial frequency
redistribution: solution of the polarized line transfer in the
non-magnetic case
Authors: Supriya, H. D.; Smitha, H. N.; Nagendra, K. N.; Ravindra,
B.; Sampoorna, M.
Bibcode: 2013MNRAS.429..275S
Altcode:
Angle-dependent partial frequency redistribution (PRD) matrices
represent the physical redistribution in the process of light scattering
on atoms. For the purpose of numerical simplicity, it is a common
practice in astrophysical literature to use the angle-averaged versions
of these matrices, in the line transfer computations. The aim of this
paper is to study the combined effects of angle-dependent PRD and the
quantum interference phenomena arising either between the fine structure
(J) states of a two-term atom or between the hyperfine structure (F)
states of a two-level atom. We restrict our attention to the case
of non-magnetic and collisionless line scattering on atoms. A rapid
method of solution based on Neumann series expansion is developed to
solve the angle-dependent PRD problem including quantum interference in
an atomic system. We discuss the differences that occur in the Stokes
profiles when angle-dependent PRD mechanism is taken into account.
Title: Polarized line formation with J-state interference in the
presence of magnetic fields: A Heuristic treatment of collisional
frequency redistribution
Authors: Smitha, H. N.; Nagendra, K. N.; Sampoorna, M.; Stenflo, J. O.
Bibcode: 2013JQSRT.115...46S
Altcode: 2012arXiv1209.0243S
An expression for the partial frequency redistribution (PRD) matrix
for line scattering in a two-term atom, which includes the J-state
interference between its fine structure line components is derived. The
influence of collisions (both elastic and inelastic) and an external
magnetic field on the scattering process is taken into account. The
lower term is assumed to be unpolarized and infinitely sharp. The
linear Zeeman regime in which the Zeeman splitting is much smaller than
the fine structure splitting is considered. The inelastic collision
rates between the different levels are included in our treatment. We
account for the depolarization caused by the collisions coupling the
fine structure states of the upper term, but neglect the polarization
transfer between the fine structure states. When the fine structure
splitting goes to zero, we recover the redistribution matrix that
represents the scattering on a two-level atom (which exhibits only
m-state interference—namely the Hanle effect). The way in which the
multipolar index of the scattering atom enters into the expression
for the redistribution matrix through the collisional branching
ratios is discussed. The properties of the redistribution matrix are
explored for a single scattering process for a L=0→1→0 scattering
transition with S=1/2 (a hypothetical doublet centered at 5000 Å and
5001 Å). Further, a method for solving the Hanle radiative transfer
equation for a two-term atom in the presence of collisions, PRD, and
J-state interference is developed. The Stokes profiles emerging from
an isothermal constant property medium are computed.
Title: Polarized Line Transfer with F-state Interference in a
Non-magnetic Medium: Partial Frequency Redistribution Effects in
the Collisionless Regime
Authors: Smitha, H. N.; Sowmya, K.; Nagendra, K. N.; Sampoorna, M.;
Stenflo, J. O.
Bibcode: 2012ApJ...758..112S
Altcode: 2012arXiv1208.6369S
Quantum interference phenomena manifest themselves in several ways
in the polarized solar spectrum formed due to coherent scattering
processes. One such effect arises due to interference between the fine
structure (J) states giving rise to multiplets. Another effect is that
which arises due to interference between the hyperfine structure (F)
states. We extend the redistribution matrix derived for the J-state
interference to the case of F-state interference. We then incorporate
it into the polarized radiative transfer equation and solve it for
isothermal constant property slab atmospheres. The relevant transfer
equation is solved using a polarized approximate lambda iteration (PALI)
technique based on operator perturbation. An alternative method derived
from the Neumann series expansion is also proposed and is found to be
relatively more efficient than the PALI method. The effects of partial
frequency redistribution and the F-state interference on the shapes
of the linearly polarized Stokes profiles are discussed. The emergent
Stokes profiles are computed for hypothetical line transitions arising
due to hyperfine structure splitting of the upper J = 3/2 and lower J =
1/2 levels of a two-level atom model with nuclear spin Is
= 3/2. We confine our attention to the non-magnetic scattering in the
collisionless regime.
Title: Polarized Partial Frequency Redistribution in Subordinate
Lines. II. Solution of the Transfer Equation with Rayleigh Scattering
Authors: Nagendra, K. N.; Sampoorna, M.
Bibcode: 2012ApJ...757...33N
Altcode:
It is quite common in line formation theory to treat scattering
in subordinate lines under the assumption of complete frequency
redistribution (CRD). The partial frequency redistribution (PRD) in
subordinate lines cannot always be approximated by CRD, especially
when the polarization state of the line radiation is taken into
account. Here we investigate the PRD effects in subordinate lines
including scattering polarization. The line formation is described by
a polarized non-LTE line transfer equation based on a two-level atom
model. We use the recently derived subordinate line redistribution
matrix. We devise polarized approximate lambda iteration methods to
solve the concerned transfer problem. The linear polarization profiles
of subordinate lines formed in non-magnetic (Rayleigh) scattering
atmospheres are discussed. We consider one-dimensional isothermal
planar model atmospheres. We show that in the polarized line transfer
calculations of subordinate lines, PRD plays as important of a role
as it does in the case of resonance lines. We also study the effect
of collisions on linear polarization profiles of subordinate lines.
Title: The effect of electron scattering redistribution on atomic
line polarization
Authors: Supriya, H. D.; Nagendra, K. N.; Sampoorna, M.; Ravindra, B.
Bibcode: 2012MNRAS.425..527S
Altcode: 2012MNRAS.tmp.3423S
The polarization of spectral lines is generated by the scattering
of angularly anisotropic incident radiation field on the atoms
in the stellar atmosphere. This atomic scattering polarization is
modified by frequency non-coherent scattering of line photons on free
electrons. With modern spectropolarimeters of high sensitivity, it
is possible to detect such changes in the spectral line polarization
caused by scattering on electrons. We present new and efficient
numerical techniques to solve the problem of line radiative transfer
with atomic and electron scattering frequency redistribution in planar
media. The evaluation and use of angle-dependent partial frequency
redistribution functions (both atomic and electron scattering type) in
the transfer equation require a lot of computing effort. In this paper,
we apply a decomposition technique to handle this numerically difficult
problem. This recently developed technique is applied for the first time
to the electron scattering partial redistribution. This decomposition
technique allows us to devise fast iterative methods of solving the
polarized line transfer equation. An approximate lambda iteration
(ALI) method and a method based on Neumann series expansion of the
polarized source vector are proposed. We show that these numerical
methods can be used to obtain a solution of the problem, when both
atomic and electron scattering partial frequency redistribution are
considered together. This is in contrast with the classical numerical
methods which require a great amount of computing time. We show the
importance of electron scattering redistribution in the far wing
line polarization, which has practical implications in the analysis
of polarized stellar or solar spectra, where non-coherent electron
scattering controls the line wing transfer.
Title: Blend lines in the polarized spectrum of the Sun
Authors: Sowmya, K.; Nagendra, K. N.; Sampoorna, M.
Bibcode: 2012MNRAS.423.2949S
Altcode: 2012MNRAS.tmp.3077S; 2015arXiv151207728S
Blend lines form an integral part of the theoretical analysis and
modelling of the polarized spectrum of the Sun. Their interaction with
other spectral lines needs to be explored and understood before we
can properly use the main spectral lines to diagnose the Sun. They are
known to cause a decrease in the polarization in the wings of the main
line on which they superpose, or in the polarization of the continuum,
when they are assumed to be formed either under the local thermodynamic
equilibrium (LTE) conditions or when their intrinsic polarizability
factor is zero. In this paper, we describe the theoretical framework
to include the blend lines formed under non-LTE conditions, in the
radiative transfer equation, and the numerical techniques to solve
it. The properties of a blend line having an intrinsic polarization
of its own and its interaction with the main line are discussed. The
results of our analysis show that the influence of the blend lines
on the main spectral lines, though small in the present context, is
important and needs to be considered when interpreting the polarized
spectral lines in the second solar spectrum.
Title: Forward-scattering Hanle effect in the solar Ca I 4227 Å line
Authors: Frisch, H.; Anusha, L. S.; Bianda, M.; Holzreuter, R.;
Nagendra, K. N.; Ramelli, R.; Sampoorna, M.; Smitha, H. N.; Stenflo,
J. O.
Bibcode: 2012EAS....55...59F
Altcode:
High sensitivity spectropolarimetric observations of the four Stokes
parameters of the solar Ca I 4227 Å line have been performed in
October 2010 at IRSOL with the ZIMPOL polarimeter, near the disk center,
outside an active region (Bianda et al. 2011). They were analyzed in
Anusha et al. 2011 with a combination of detailed radiative transfer
modelling of the Hanle effect for the linear polarization and weak
field Zeeman approximation for the circular polarization. This approach
made possible a unique determination of the magnetic field vector at
various positions along the slit of the spectrograph. A summary of
the observations and of their analysis is presented here.
Title: J-state interference signatures in the second solar
spectrum. Modeling the Cr i triplet at 5204-5208 Å
Authors: Smitha, H. N.; Nagendra, K. N.; Stenflo, J. O.; Bianda, M.;
Sampoorna, M.; Ramelli, R.; Anusha, L. S.
Bibcode: 2012A&A...541A..24S
Altcode: 2012arXiv1203.4934S
The scattering polarization in the solar spectrum is traditionally
modeled with each spectral line treated separately, but this is
generally inadequate for multiplets where J-state interference
plays a significant role. Through simultaneous observations of all
the 3 lines of a Cr i triplet, combined with realistic radiative
transfer modeling of the data, we show that it is necessary to include
J-state interference consistently when modeling lines with partially
interacting fine structure components. Polarized line formation theory
that includes J-state interference effects together with partial
frequency redistribution for a two-term atom is used to model the
observations. Collisional frequency redistribution is also accounted
for. We show that the resonance polarization in the Cr i triplet is
strongly affected by the partial frequency redistribution effects in
the line core and near wing peaks. The Cr i triplet is quite sensitive
to the temperature structure of the photospheric layers. Our complete
frequency redistribution calculations in semi-empirical models of the
solar atmosphere cannot reproduce the observed near wing polarization or
the cross-over of the Stokes Q/I line polarization about the continuum
polarization level that is due to the J-state interference. When
however partial frequency redistribution is included, a good fit to
these features can be achieved. Further, to obtain a good fit to the
far wings, a small temperature enhancement of the FALF model in the
photospheric layers is necessary.
Title: Polarized Partial Frequency Redistribution in Subordinate
Lines. I. Resonance Scattering with Collisions
Authors: Sampoorna, M.
Bibcode: 2012ApJ...745..189S
Altcode:
Using a previously established theory, we derive a suitable form of the
laboratory frame redistribution matrix for the resonance scattering in
subordinate lines, allowing for the radiative as well as collisional
broadening of both atomic levels involved. The lower level, though
broadened, is assumed to be unpolarized. The elastic collisions both
in the upper and lower levels are taken into account. We show that, in
situations, when elastic collisions in the lower level can be neglected,
the redistribution matrix for subordinate lines takes a form that is
analogous to the corresponding case of resonance lines. Further, in
the case of no-lower-level interactions (i.e., infinitely sharp lower
level), we recover the redistribution matrix for resonance lines. We
express the redistribution matrix for subordinate lines in terms
of the irreducible spherical tensors for polarimetry. For practical
applications in one-dimensional polarized radiative transfer problem,
we derive the azimuth averaged subordinate line redistribution matrix.
Title: Radiative transfer with J-state interference in a two-term
atom. Partial frequency redistribution in the non-magnetic case
Authors: Smitha, H. N.; Nagendra, K. N.; Sampoorna, M.; Stenflo, J. O.
Bibcode: 2011A&A...535A..35S
Altcode:
Context. Quantum interference phenomena play a fundamental role in
the formation of linear polarization that arises from scattering
processes in multiplets of the solar spectrum. In particular,
the J-state interference between different line components of a
multiplet (arising from transitions in a two-term atom) produces
significant effects in the linearly polarized spectra.
Aims:
We aim to solve the polarized radiative transfer equation for a
two-term atom with the unpolarized lower term in isothermal slabs,
including the effect of the interference between the upper J-states
and partial frequency redistribution (PRD). We consider only the case
of non-magnetic scattering.
Methods: The PRD matrix for the
J-state interference derived in previous works is incorporated into
the polarized transfer equation. The standard form of the two-level
atom transfer equation is extended to a two-term atom. The transfer
problem is then solved using a traditional polarized approximate lambda
iteration method.
Results: We show how the PRD and the J-state
interference together affect the shapes of the (I,Q/I) profiles. We
present the benchmark solutions for isothermal, constant-property
slabs of a given optical thickness. We consider a hypothetical doublet
produced by an L = 0 → 1 → 0 scattering transition with spin S =
1/2. We present the results in the form of Stokes (I,Q/I) profiles for
different values of (i) the line separation, (ii) optical thickness,
(iii) thermalization parameter, and (iv) the continuum opacity.
Title: Spectral line polarization with angle-dependent partial
frequency redistribution. IV. Scattering expansion method for the
Hanle effect
Authors: Nagendra, K. N.; Sampoorna, M.
Bibcode: 2011A&A...535A..88N
Altcode:
Context. The partial frequency redistribution (PRD) effects in line
scattering are necessary ingredients for interpreting the linear
polarization observed in strong resonance lines. It is a common
practice to use angle-averaged PRD functions for simplicity (obtained
by averaging over all scattering angles). It has been established that
the use of angle-dependent PRD functions instead of angle-averaged
functions is essential for weak fields.
Aims: Here we present
an efficient iterative method to solve the polarized line radiative
transfer equation in weak magnetic fields using angle-dependent
PRD functions.
Methods: Based on the theory of Stokes vector
decomposition for the Hanle effect combined with the Fourier azimuthal
expansion of the angle-dependent PRD function, we try to formulate an
efficient numerical method of solving the concerned transfer problem
in one-dimensional media. This iterative method (referred to as the
scattering expansion method, SEM) is based on a series expansion of
the polarized source vector in mean number of scatterings (Neumann
series expansion). We apply the SEM approach to handle both the exact
and various approximate forms of the Hanle scattering redistribution
matrix.
Results: The SEM is shown to be an efficient method
to solve angle-dependent PRD problems involving the Hanle effect. We
show that compared to the earlier methods such as the perturbation
methods, the SEM is stable and faster. We find that angle-dependent
PRD significantly affects the Stokes U parameter.
Title: Analysis of the Forward-scattering Hanle Effect in the Ca I
4227 Å Line
Authors: Anusha, L. S.; Nagendra, K. N.; Bianda, M.; Stenflo, J. O.;
Holzreuter, R.; Sampoorna, M.; Frisch, H.; Ramelli, R.; Smitha, H. N.
Bibcode: 2011ApJ...737...95A
Altcode:
Coherent scattering of limb-darkened radiation is responsible for the
generation of the linearly polarized spectrum of the Sun (the Second
Solar Spectrum). This Second Solar Spectrum is usually observed near the
limb of the Sun, where the polarization amplitudes are largest. At the
center of the solar disk the linear polarization is zero for an axially
symmetric atmosphere. Any mechanism that breaks the axial symmetry (like
the presence of an oriented magnetic field, or resolved inhomogeneities
in the atmosphere) can generate a non-zero linear polarization. In the
present paper we study the linear polarization near the disk center
in a weakly magnetized region, where the axisymmetry is broken. We
present polarimetric (I, Q/I, U/I, and V/I) observations of the Ca
I 4227 Å line recorded around μ = cos θ = 0.9 (where θ is the
heliocentric angle) and a modeling of these observations. The high
sensitivity of the instrument (ZIMPOL-3) makes it possible to measure
the weak polarimetric signals with great accuracy. The modeling of
these high-quality observations requires the solution of the polarized
radiative transfer equation in the presence of a magnetic field. For
this we use standard one-dimensional model atmospheres. We show that the
linear polarization is mainly produced by the Hanle effect (rather than
by the transverse Zeeman effect), while the circular polarization is due
to the longitudinal Zeeman effect. A unique determination of the full
\bm {B} vector may be achieved when both effects are accounted for. The
field strengths required for the simultaneous fitting of Q/I, U/I, and
V/I are in the range 10-50 G. The shapes and signs of the Q/I and U/I
profiles are highly sensitive to the orientation of the magnetic field.
Title: Spectral line polarization with angle-dependent partial
frequency redistribution. III. Single scattering approximation for
the Hanle effect
Authors: Sampoorna, M.
Bibcode: 2011A&A...532A..52S
Altcode:
Context. The solar limb observations in spectral lines display evidence
of linear polarization, caused by non-magnetic resonance scattering
process. This polarization is modified by weak magnetic fields - the
process of the Hanle effect. These two processes serve as diagnostic
tools for weak solar magnetic field determination. In modeling the
polarimetric observations the partial frequency redistribution (PRD)
effects in line scattering have to be accounted for. For simplicity, it
is common practice to use PRD functions averaged over all scattering
angles. For weak fields, it has been established that the use of
angle-dependent PRD functions instead of angle-averaged functions is
essential.
Aims: We introduce a single scattering approximation
to the problem of polarized line radiative transfer in weak magnetic
fields with an angle-dependent PRD. This helps us to rapidly compute
an approximate solution to the difficult and numerically expensive
problem of polarized line formation with angle-dependent PRD.
Methods: We start from the recently developed Stokes vector
decomposition technique combined with the Fourier azimuthal expansion
for angle-dependent PRD with the Hanle effect. In this decomposition
technique, the polarized radiation field (I, Q, U) is decomposed
into an infinite set of cylindrically symmetric Fourier coefficients
tilde I(k)K_Q, where K = 0,2, with - K ≤ Q ≤ + K,
and k is the order of the Fourier coefficients (k takes values from
- ∞ to + ∞). In the single scattering approximation, the effect
of the magnetic field on the Stokes I is neglected, so that it can
be computed using the standard non-local thermodynamic equilibrium
(non-LTE) scalar line transfer equation. In the case of angle-dependent
PRD, we further assume that the Stokes I is cylindrically symmetric
and given by its dominant term tilde I(0)0_0. Keeping
only the contribution from tilde I(0)0_0 in the source
terms for the K = 2 components (which give rise to Stokes Q and
U), the value of k is limited to 0, ± 1, ± 2. As a result, the
dimensionality of the problem is reduced from infinity to 25 for
the K = 2 Fourier coefficients.
Results: We show that the
single scattered solution provides a reasonable approximation to
the emergent polarization computed using the polarized line transfer
equation including angle-dependent PRD and the Hanle effect. While
the full problem is computationally expensive, the single scattering
approximation provides a faster method of solution. The presence of
elastic collisions particularly enhances the domain of applicability of
this approximation.