The Temperature Structure in Accretion Flows onto Massive Protostars
Abstract
Radiation transfer problems involved in the infall of dust and gas during star formation are studied. Dust properties are discussed, and modifications of spherical radiative transfer equations are presented that permit forward scattering by dust to be treated for the small size of the star relative to the inner radius of the shell. A procedure for deriving the stellar radiation field incident on the inner edge of the shell is developed. The temperature correction procedure of Cassinelli and Hartmann (1975) for extended stellar atmospheres is modified so that the multitemperature nature of the grains in the cloud may be derived. Temperature distributions for three schematic models in which the density is prespecified are discussed. Radiative acceleration of grains is addressed, showing that the proper mean opacity differs by a large factor from the Rosseland mean opacity that is commonly used. Emergent fluxes for the models are given.
- Publication:
-
The Astrophysical Journal
- Pub Date:
- November 1986
- DOI:
- 10.1086/164676
- Bibcode:
- 1986ApJ...310..207W
- Keywords:
-
- Gas Temperature;
- Pre-Main Sequence Stars;
- Protostars;
- Star Formation;
- Stellar Mass Accretion;
- Cosmic Dust;
- Gas Mixtures;
- Particle Acceleration;
- Radiative Transfer;
- Astrophysics;
- STARS: ACCRETION;
- STARS: FORMATION;
- STARS: PRE--MAIN-SEQUENCE