On the Interpretation of Far-infrared Spectral Energy Distributions. I: The 850 μm Molecular Mass Estimator

Abstract

We use a suite of cosmological zoom galaxy formation simulations and dust radiative transfer calculations to explore the use of the monochromatic 850~μ m luminosity (L ,850) as a molecular gas mass (M mol) estimator in galaxies between 0 < z < 9.5 for a broad range of masses. For our fiducial simulations, where we assume the dust mass is linearly related to the metal mass, we find that empirical L ,850-M mol calibrations accurately recover the molecular gas mass of our model galaxies, and that the L ,850-dependent calibration is preferred. We argue the major driver of scatter in the L ,850-M mol relation arises from variations in the molecular gas to dust mass ratio, rather than variations in the dust temperature, in agreement with the previous study of Liang et al. Emulating a realistic measurement strategy with ALMA observing bands that are dependent on the source redshift, we find that estimating S ,850 from continuum emission at a different frequency contributes 10-20\% scatter to the L ,850-M mol relation. This additional scatter arises from a combination of mismatches in assumed Tdust and β values, as well as the fact that the SEDs are not single-temperature blackbodies.Finally we explore the impact of a dust prescription in which the dust-to-metals ratio varies with metallicity. Though the resulting mean dust temperatures are 50\% higher, the dust mass is significantly decreased for low-metallicity halos. As a result, the observationally calibrated L ,850-M mol relation holds for massive galaxies, independent of the dust model, but below L ,8501028 erg s-1 (metallicities 10( Z/ Z) -0.8) we expect galaxies may deviate from literature observational calibrations by 0.5 dex.