On the Absorption and Emission Properties of Interstellar Grains

Our current understanding of the absorption and emission properties of interstellar grains are reviewed. The constraints placed by the Kramers-Kronig relation on the wavelength-dependence and the maximum allowable quantity of the dust absorption are discussed. Comparisons of the opacities (mass absorption coefficients) derived from interstellar dust models with those directly estimated from observations are presented.Comment: invited talk for "The Spectral Energy Distribution of Gas-Rich Galaxies: Confronting Models with Data" (Heidelberg, Germany; 4--8 October 2004), edited by C.C. Popescu & R.J. Tuffs, AIP Conf. Ser., in press; (11 pages, no figures, no tables

Interstellar Silicon Depletion and the Ultraviolet Extinction

Spinning small silicate grains were recently invoked to account for the Galactic foreground anomalous microwave emission. These grains, if present, will absorb starlight in the far ultraviolet (UV). There is also renewed interest in attributing the enigmatic 2175 Angstrom interstellar extinction bump to small silicates. To probe the role of silicon in the UV extinction, we explore the relations between the amount of silicon required to be locked up in silicates [Si/H]_{dust} and the 2175 Angstrom bump or the far-UV extinction rise, based on an analysis of the extinction curves along 46 Galactic sightlines for which the gas-phase silicon abundance [Si/H]_{gas} is known. We derive [Si/H]_{dust} either from {[Si/H]_{ISM} - [Si/H]_{gas}} or from the Kramers-Kronig relation which relates the wavelength-integrated extinction to the total dust volume, where [Si/H]_{ISM} is the interstellar silicon reference abundance and taken to be that of proto-Sun or B stars. We also derive [Si/H]_{dust} from fitting the observed extinction curves with a mixture of amorphous silicates and graphitic grains. We find that in all three cases [Si/H]_{dust} shows no correlation with the 2175 Angstrom bump, while the carbon depletion [C/H]_{dust} tends to correlate with the 2175 Angstrom bump. This supports carbon grains instead of silicates as the possible carrier of the 2175 Angstrom bump. We also find that neither [Si/H]_{dust} nor [C/H]_{dust} alone correlates with the far-UV extinction, suggesting that the far-UV extinction is a combined effect of small carbon grains and silicates.Comment: 38 pages, 15 figures, 2 tables; accepted for publication in The Astrophysical Journal (2017). arXiv admin note: text overlap with arXiv:1507.0659