Abstract
We present a method to estimate the total gas column density, dust-to-gas and
dust-to-metal ratios of distant galaxies from rest-frame optical spectra. The
technique exploits the sensitivity of certain optical lines to changes in
depletion of metals onto dust grains and uses photo-ionization models to
constrain these physical ratios along with the metallicity (Z) and dust column
density. We compare our gas column density estimates with HI and CO gas mass
estimates in nearby galaxies to show that we recover their total gas mass
surface density to within a factor of 2 up to a total surface gas mass density
of ~75 Mo/pc^2. Our technique is independent of the conversion factor of CO to
H2 and we show that a Z-dependent XCO is required to achieve good agreement
between our measurements and that provided by CO and HI. However we also show
that our method can not be reliably aperture corrected to total gas mass. We
calculate dust-to-gas ratios for all star-forming galaxies in the SDSS DR7 and
show the resulting dependence on Z agrees well with the trend inferred from
modelling of the dust emission of nearby galaxies using FIR data. We also
present estimates of the variation of the dust-to-metal ratio with Z and show
that this is poorly constrained at Z<~0.5Z_sun. We end with a study of the
inventory of gas in the central regions, defined both in terms of a fixed
physical radius and as a fixed fraction of the half-light radius, of ~70,000
star-forming galaxies from the Sloan Digital Sky Survey. We show that their
central gas content and gas depletion times are not accurately predicted by a
single parameter, but in agreement with recent studies we find that a
combination of the M* and some measure of central concentration provides a good
predictor of gas content in galaxies. We also identify a population of galaxies
with low surface densities of stars and very long gas depletion times.
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