English

Parameterizing the interstellar dust temperature

Astrophysics of Galaxies 2017-08-09 v2 Cosmology and Nongalactic Astrophysics

Abstract

The temperature of interstellar dust particles is of great importance to astronomers. It plays a crucial role in the thermodynamics of interstellar clouds, because of the gas-dust collisional coupling. It is also a key parameter in astrochemical studies that governs the rate at which molecules form on dust. In 3D (magneto)hydrodynamic simulations often a simple expression for the dust temperature is adopted, because of computational constraints, while astrochemical modelers tend to keep the dust temperature constant over a large range of parameter space. Our aim is to provide an easy-to-use parametric expression for the dust temperature as a function of visual extinction (AVA_{\rm V}) and to shed light on the critical dependencies of the dust temperature on the grain composition. We obtain an expression for the dust temperature by semi-analytically solving the dust thermal balance for different types of grains and compare to a collection of recent observational measurements. We also explore the effect of ices on the dust temperature. Our results show that a mixed carbonaceous-silicate type dust with a high carbon volume fraction matches the observations best. We find that ice formation allows the dust to be warmer by up to 15% at high optical depths (AV>20A_{\rm V}> 20 mag) in the interstellar medium. Our parametric expression for the dust temperature is presented as Td=[11+5.7×tanh(0.61log10(AV))]χuv1/5.9T_{\rm d} = \left[ 11 + 5.7\times \tanh\bigl( 0.61 - \log_{10}(A_{\rm V})\bigr) \right] \, \chi_{\rm uv}^{1/5.9}, where χuv\chi_{\rm uv} is in units of the Draine (1978) UV field

Keywords

Cite

@article{arxiv.1704.02763,
  title  = {Parameterizing the interstellar dust temperature},
  author = {S. Hocuk and L. Szucs and P. Caselli and S. Cazaux and M. Spaans and G. B. Esplugues},
  journal= {arXiv preprint arXiv:1704.02763},
  year   = {2017}
}

Comments

16 pages, 17 figures, 4 tables. Accepted for publication in A&A. Version 2: the omission of factor 0.921 in equation 4 is corrected

R2 v1 2026-06-22T19:12:35.605Z