Modeling the H2O submillimeter emission in extragalactic sources

Abstract

Recent observational studies have shown that H2O emission at (rest) submillimeter wavelengths is ubiquitous in infrared galaxies, both in the local and in the early Universe, suggestive of far-infrared pumping of H2O by dust in warm regions. In this work, models are presented that show that (i) the highest-lying H2O lines (Eupper>400 K) are formed in very warm (Tdust>~90 K) regions and require high H2O columns (NH2O>~3x1017 cm-2), while lower lying lines can be efficiently excited with Tdust~45-75 K and NH2O~(0.5-2)x1017 cm-2; (ii) significant collisional excitation of the lowest lying (Eupper<200 K) levels, which enhances the overall LH2O-LIR ratios, is identified in sources where the ground-state para-H2O 111-000 line is detected in emission; (iii) the H2O-to-infrared (8-1000 um) luminosity ratio is expected to decrease with increasing Tdust for all lines with Eupper<~300 K, as has recently been reported in a sample of LIRGs, but increases with Tdust for the highest lying H2O lines (Eupper>400 K); (iv) we find theoretical upper limits for LH2O/LIR in warm environments, owing to H2O line saturation; (v) individual models are presented for two very different prototypical galaxies, the Seyfert 2 galaxy NGC 1068 and the nearest ultraluminous infrared galaxy Arp 220, showing that the excited submillimeter H2O emission is dominated by far-infrared pumping in both cases; (vi) the LH2O-LIR correlation previously reported in observational studies indicates depletion or exhaustion time scales, tdep=Sigmagas/SigmaSFR, of <~12 Myr for star-forming sources where lines up to Eupper=300 K are detected, in agreement with the values previously found for (U)LIRGs from HCN millimeter emission...