Radiative Transfer in Dynamic Stellar Atmospheres

Observations and magnetohydrodynamic simulations of solar and stellar atmospheres reveal an intermittent behavior or steep gradients in physical parameters, such as magnetic field, temperature, and bulk velocities. The numerical solution of the stationary radiative transfer equation is particularly challenging in such situations, because standard numerical methods may perform very inefficiently in the absence of local smoothness. However, a rigorous investigation of the numerical treatment of the radiative transfer equation in discontinuous media is still lacking. The aim of this work is to expose the limitations of standard convergence analyses for this problem and to identify the relevant issues. Moreover, specific numerical tests are performed. These show that discontinuities in the atmospheric physical parameters effectively induce first-order discontinuities in the radiative transfer equation, reducing the accuracy of the solution and thwarting high-order convergence. In addition, a survey of the existing numerical schemes for discontinuous ordinary differential systems and interpolation techniques for discontinuous discrete data is given, evaluating their applicability to the radiative transfer problem.

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Models for the Circumstellar Envelopes of Be Stars: (Review Paper)

Symposium - International Astronomical Union ◽

10.1017/s0074180900011505 ◽

1976 ◽

Vol 70 ◽

pp. 335-370 ◽

Cited By ~ 3

Author(s):

J. M. Marlborough

Keyword(s):

Ad Hoc ◽

Review Paper ◽

Circumstellar Matter ◽

Be Stars ◽

Circumstellar Envelopes ◽

Structure And Dynamics ◽

Restricted Problems ◽

Be Star ◽

Physical Phenomena

A survey is presented of the theoretical attempts to determine the structure of the circumstellar matter around Be stars. The general equations describing the structure and dynamics of Be star envelopes are given. The complications introduced by various physical phenomena are briefly discussed and initial attempts to solve restricted problems are considered. The various ad hoc models proposed for Be stars are discussed and comparisons of the observations with predictions of these models are illustrated. The strengths and weaknesses of these models are evaluated and areas where progress is being or should be made are considered.

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Modeling of the Be Stars

Proceedings of the International Astronomical Union ◽

10.1017/s1743921311027517 ◽

2011 ◽

Vol 7 (S282) ◽

pp. 261-262 ◽

Cited By ~ 1

Author(s):

K. Šejnová ◽

V. Votruba ◽

P. Koubský

Keyword(s):

Radiative Transfer ◽

Parameter Space ◽

Three Dimensional ◽

Line Of Sight ◽

Circumstellar Disk ◽

Physical Parameters ◽

Be Stars ◽

Star Program ◽

Be Star ◽

Moving Media

AbstractThe Be stars are still a big unknown in respect to the origin and geometry of the circumstellar disk around the star. Program shellspec is designed to solve the simple radiative transfer along the line of sight in three-dimensional moving media. Our goal was to develop an effective method to search in parameter space, which can allow us to find a good estimate of the physical parameters of the disk. We also present here our results for Be star 60 Cyg using the modified code.

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Radiative Transfer. I. The Flux-Temperature Relation and Non-Gray Stellar Atmospheres

The Astrophysical Journal ◽

10.1086/149137 ◽

1967 ◽

Vol 148 ◽

pp. 207 ◽

Cited By ~ 4

Author(s):

Louis Henyey

Keyword(s):

Radiative Transfer ◽

Stellar Atmospheres ◽

Temperature Relation

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The Palaeoclimate and Terrestrial Exoplanet Radiative Transfer Model Intercomparison Project (PALAEOTRIP): experimental design and protocols

Geoscientific Model Development ◽

10.5194/gmd-10-3931-2017 ◽

2017 ◽

Vol 10 (11) ◽

pp. 3931-3940 ◽

Cited By ~ 1

Author(s):

Colin Goldblatt ◽

Lucas Kavanagh ◽

Maura Dewey

Keyword(s):

Radiative Transfer ◽

Ad Hoc ◽

Climate Science ◽

Radiative Transfer Model ◽

Transfer Model ◽

Climate Modelling ◽

Atmospheric Conditions ◽

Model Intercomparison ◽

Radiative Transfer Calculation ◽

Intercomparison Project

Abstract. Accurate radiative transfer calculation is fundamental to all climate modelling. For deep palaeoclimate, and increasingly terrestrial exoplanet climate science, this brings both the joy and the challenge of exotic atmospheric compositions. The challenge here is that most standard radiation codes for climate modelling have been developed for modern atmospheric conditions and may perform poorly away from these. The palaeoclimate or exoclimate modeller must either rely on these or use bespoke radiation codes, and in both cases rely on either blind faith or ad hoc testing of the code. In this paper, we describe the protocols for the Palaeoclimate and Terrestrial Exoplanet Radiative Transfer Model Intercomparison Project (PALAEOTRIP) to systematically address this. This will compare as many radiation codes used for palaeoclimate or exoplanets as possible, with the aim of identifying the ranges of far-from-modern atmospheric compositions in which the codes perform well. This paper describes the experimental protocol and invites community participation in the project through 2017–2018.

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A novel fourth-order WENO interpolation technique

Astronomy and Astrophysics ◽

10.1051/0004-6361/201834761 ◽

2019 ◽

Vol 624 ◽

pp. A104

Author(s):

Gioele Janett ◽

Oskar Steiner ◽

Ernest Alsina Ballester ◽

Luca Belluzzi ◽

Siddhartha Mishra

Keyword(s):

Radiative Transfer ◽

Fourth Order ◽

Convex Combination ◽

High Order ◽

Stellar Atmospheres ◽

High Order Accuracy ◽

Oscillatory Property ◽

Order Accuracy ◽

Interpolation Technique ◽

Weno Interpolation

Context. Several numerical problems require the interpolation of discrete data that present at the same time (i) complex smooth structures and (ii) various types of discontinuities. The radiative transfer in solar and stellar atmospheres is a typical example of such a problem. This calls for high-order well-behaved techniques that are able to interpolate both smooth and discontinuous data. Aims. This article expands on different nonlinear interpolation techniques capable of guaranteeing high-order accuracy and handling discontinuities in an accurate and non-oscillatory fashion. The final aim is to propose new techniques which could be suitable for applications in the context of numerical radiative transfer. Methods. We have proposed and tested two different techniques. Essentially non-oscillatory (ENO) techniques generate several candidate interpolations based on different substencils. The smoothest candidate interpolation is determined from a measure for the local smoothness, thereby enabling the essentially non-oscillatory property. Weighted ENO (WENO) techniques use a convex combination of all candidate substencils to obtain high-order accuracy in smooth regions while keeping the essentially non-oscillatory property. In particular, we have outlined and tested a novel well-performing fourth-order WENO interpolation technique for both uniform and nonuniform grids. Results. Numerical tests prove that the fourth-order WENO interpolation guarantees fourth-order accuracy in smooth regions of the interpolated functions. In the presence of discontinuities, the fourth-order WENO interpolation enables the non-oscillatory property, avoiding oscillations. Unlike Bézier and monotonic high-order Hermite interpolations, it does not degenerate to a linear interpolation near smooth extrema of the interpolated function. Conclusion. The novel fourth-order WENO interpolation guarantees high accuracy in smooth regions, while effectively handling discontinuities. This interpolation technique might be particularly suitable for several problems, including a number of radiative transfer applications such as multidimensional problems, multigrid methods, and formal solutions.

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Parameterization of single-scattering properties of snow

The Cryosphere Discussions ◽

10.5194/tcd-9-873-2015 ◽

2015 ◽

Vol 9 (1) ◽

pp. 873-926 ◽

Cited By ~ 3

Author(s):

P. Räisänen ◽

A. Kokhanovsky ◽

G. Guyot ◽

O. Jourdan ◽

T. Nousiainen

Keyword(s):

Radiative Transfer ◽

Phase Function ◽

Ad Hoc ◽

Single Scattering ◽

Climate Impacts ◽

Spherical Particles ◽

Blowing Snow ◽

Equivalent Radius ◽

Angular Scattering ◽

Spherical Grains

Abstract. Snow consists of non-spherical grains of various shapes and sizes. Still, in many radiative transfer applications, single-scattering properties of snow have been based on the assumption of spherical grains. More recently, second-generation Koch fractals have been employed. While they produce a relatively flat phase function typical of deformed non-spherical particles, this is still a rather ad-hoc choice. Here, angular scattering measurements for blowing snow conducted during the CLimate IMpacts of Short-Lived pollutants In the Polar region (CLIMSLIP) campaign at Ny Ålesund, Svalbard, are used to construct a reference phase function for snow. Based on this phase function, an optimized habit combination (OHC) consisting of severely rough (SR) droxtals, aggregates of SR plates and strongly distorted Koch fractals is selected. The single-scattering properties of snow are then computed for the OHC as a function of wavelength λ and snow grain volume-to-projected area equivalent radius rvp. Parameterization equations are developed for λ = 0.199–2.7 μm and rvp = 10–2000 μm, which express the single-scattering co-albedo β, the asymmetry parameter g and the phase function P11 as functions of the size parameter and the real and imaginary parts of the refractive index. The parameterizations are analytic and simple to use in radiative transfer models. Compared to the reference values computed for the OHC, the accuracy of the parameterization is very high for β and g. This is also true for the phase function parameterization, except for strongly absorbing cases (β > 0.3). Finally, we consider snow albedo and reflected radiances for the suggested snow optics parameterization, making comparisons to spheres and distorted Koch fractals.

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