We present the results of a three-dimensional Monte Carlo radiative transfer code for starless molecular cloud cores heated by an external isotropic or non-isotropic interstellar radiation field. The code computes the dust temperature distribution inside model clouds with specified but arbitrary density profiles. In particular we examine in detail spherical (Bonnor-Ebert) clouds, axisymmetric and non-axisymmetric toroids, and clouds heated by an external stellar source in addition to the general interstellar field. For these configurations, the code also computes maps of the emergent intensity at different wavelengths and arbitrary viewing angle, that can be compared directly with continuum maps of prestellar cores. In the approximation whe...
We combine a Monte Carlo radiative transfer code with an SPH code, so that – assuming thermal equil...
The Earth’s radiative cooling is a key driver of climate and due to the complexity of the radia-tive...
The Monte Carlo (MC) method is an effective approach to simulate the radiative transfer in an inhomo...
We implement a Monte Carlo radiative transfer method, that uses a large number of monochromatic lumi...
We use our Monte Carlo radiative transfer code to study non-embedded prestellar cores and cores that...
Constraints on the density and thermal 3D structure of the dense molecular cloud core ρ Oph D are d...
We use our Monte Carlo radiative transfer code to study non-embedded prestellar cores and cores that...
International audienceConstraints on the density and thermal 3D structure of the dense molecular clo...
We present 2D Monte Carlo radiative transfer simulations of prestellar cores. We consider two types ...
Constraints on the density and thermal 3D structure of the dense molecular cloud core rho Oph D ar...
We will present radiative transfer calculations of non-embedded and embedded prestellar cores perfor...
The Monte Carlo (MC) method is an effective approach to simulate the radiative transfer in an inhomo...
We present 2D Monte Carlo radiative transfer simulations of flattened prestellar cores. We argue the...
We combine a Monte Carlo radiative transfer code with an SPH code, so that – assuming thermal equil...
The Earth’s radiative cooling is a key driver of climate and due to the complexity of the radia-tive...
The Monte Carlo (MC) method is an effective approach to simulate the radiative transfer in an inhomo...
We implement a Monte Carlo radiative transfer method, that uses a large number of monochromatic lumi...
We use our Monte Carlo radiative transfer code to study non-embedded prestellar cores and cores that...
Constraints on the density and thermal 3D structure of the dense molecular cloud core ρ Oph D are d...
We use our Monte Carlo radiative transfer code to study non-embedded prestellar cores and cores that...
International audienceConstraints on the density and thermal 3D structure of the dense molecular clo...
We present 2D Monte Carlo radiative transfer simulations of prestellar cores. We consider two types ...
Constraints on the density and thermal 3D structure of the dense molecular cloud core rho Oph D ar...
We will present radiative transfer calculations of non-embedded and embedded prestellar cores perfor...
The Monte Carlo (MC) method is an effective approach to simulate the radiative transfer in an inhomo...
We present 2D Monte Carlo radiative transfer simulations of flattened prestellar cores. We argue the...
We combine a Monte Carlo radiative transfer code with an SPH code, so that – assuming thermal equil...
The Earth’s radiative cooling is a key driver of climate and due to the complexity of the radia-tive...
The Monte Carlo (MC) method is an effective approach to simulate the radiative transfer in an inhomo...