Abstract
Context. In order to constrain the models describing circumstellar environments, it is necessary to solve the radiative transfer equation in the presence of absorption and scattering, coupled with the equation for radiative equilibrium. However, solving this problem requires much CPU time, which makes the use of automatic minimisation procedures to characterise these environments challenging. Aims. In this context, the use of approximate methods is of primary interest. One promising candidate method is the flux-limited diffusion (FLD), which recasts the radiative transfer problem into a non-linear diffusion equation. One important aspect for the accuracy of the method lies in the implementation of appropriate boundary conditions (BCs). We present new BCs for the FLD approximation in circumstellar environments that we apply here to spherically symmetric envelopes. Methods. At the inner boundary, the entering flux (coming from the star and from the envelope itself) may be written in the FLD formalism and provides us with an adequate BC. At the free outer boundary, we used the FLD formalism to constrain the ratio of the mean radiation intensity over the emerging flux. In both cases we derived non-linear mixed BCs relating the surface values of the mean specific intensity and its gradient. We implemented these conditions and compared the results with previous benchmarks and the results of a Monte Carlo radiative transfer code. A comparison with results derived from BCs that were previously proposed in other contexts is presented as well. Results. For all the tested cases, the average relative difference with the benchmark results is below 2% for the temperature profile and below 6% for the corresponding spectral energy distribution or the emerging flux. We point out that the FLD method together with the new outer BC also allows us to derive an approximation for the emerging flux. This feature avoids additional formal solutions for the radiative transfer equation in a set of rays (ray-tracing computations). Conclusions. The FLD approximation together with the proposed new BCs performs well and captures the main physical properties of the radiative equilibrium in spherical circumstellar envelopes.
Highlights
The study of circumstellar environments at different stages of stellar evolution is of crucial importance
The envelope is heated by the radiation, and a radiative equilibrium can be reached in which the envelope emits radiation in the infrared domain
We present new boundary conditions (BCs) for the flux-limited diffusion (FLD) theory in circumstellar environments that we tested and implemented in the case of spherically symmetric envelopes
Summary
The study of circumstellar environments at different stages of stellar evolution is of crucial importance. One promising candidate is the flux-limited diffusion (FLD), introduced by Levermore & Pomraning (1981) (L&P hereafter) This description numerically simplifies the problem by recasting the radiative transfer equation into a non-linear diffusion equation for the mean specific intensity of the radiation field Sonnhalter et al (1995), Yorke & Sonnhalter (2002) used the FLD to solve the frequencydependent radiative transfer to model protostellar discs and massive star formation, respectively In these studies, the central star was treated as an additional source and the specific mean intensity Jν at the outer edge of the media was set to be equal to the Planck function Bν(Tout), with a prescribed temperature Tout at the boundary.
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