3D continuum radiative transfer in complex dust configurations -: II.: 3D structure of the dense molecular cloud core ρ Oph D

Constraints on the density and thermal 3D structure of the dense molecular cloud core rho Oph D are derived from a detailed 3D radiative transfer modeling. Two ISOCAM images at 7 and 15 mu m are fitted simultaneously by representing the dust distribution in the core with a series of 3D Gaussian density profiles. Size, total density and position of the Gaussians are optimized by simulated annealing to obtain a 2D column density map. The projected core density has a complex elongated pattern with two peaks. We propose a new method to calculate an approximate temperature in an externally illuminated complex 3D structure from a mean optical depth. This T-tau method is applied to a 1.3 mm map obtained with the IRAM30m telescope to find the approximate 3D density and temperature distribution of the core rho Oph D. The spatial 3D distribution deviates strongly from spherical symmetry. The elongated structure is in general agreement with recent gravo- turbulent collapse calculations for molecular clouds. We discuss possible ambiguities of the background determination procedure, errors of the maps, the accuracy of the T-tau method and the influence of the assumed dust particle sizes and properties.