The SAMI Galaxy Survey: a new method to estimate molecular gas surface densities from star formation rates

Stars form in cold molecular clouds. However, molecular gas is difficult to observe because the most abundant molecule (H-2) lacks a permanent dipole moment. Rotational transitions of CO are often used as a tracer of H-2, but CO is much less abundant and the conversion from CO intensity to H-2 mass...

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Bibliographic Details
Published in:Monthly Notices of the Royal Astronomical Society
Main Authors: Federrath, Christoph, Salim, Diane M., Medling, Anne M., Davies, Rebecca L., Yuan, Tiantian, Bian, Fuyan, Groves, Brent A., Ho, I-Ting, Sharp, Robert, Kewley, Lisa J., Sweet, Sarah M., Richards, Samuel N., Bryant, Julia J., Brough, Sarah, Croom, Scott, Scott, Nicholas, Lawrence, Jon, Konstantopoulos, Iraklis, Goodwin, Michael
Format: Article in Journal/Newspaper
Language:English
Published: Oxford University Press 2017
Subjects:
Mass Assembly Gama
Modeling Co Emission
On Spiral Galaxies
Formation Law
Milky-Way
Interstellar Turbulence
Nearby Galaxies
Data Release
3-Dimensional Distribution
Probability-Distribution
Milky Way
sami
Online Access:https://espace.library.uq.edu.au/view/UQ:44d4653/UQ44d4653_OA.pdf
https://espace.library.uq.edu.au/view/UQ:44d4653
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Summary:Stars form in cold molecular clouds. However, molecular gas is difficult to observe because the most abundant molecule (H-2) lacks a permanent dipole moment. Rotational transitions of CO are often used as a tracer of H-2, but CO is much less abundant and the conversion from CO intensity to H-2 mass is often highly uncertain. Here we present a new method for estimating the column density of cold molecular gas (Sigma(gas)) using optical spectroscopy. We utilize the spatially resolved H alpha maps of flux and velocity dispersion from the Sydney-AAO Multi-object Integral field spectrograph (SAMI) Galaxy Survey. We derive maps of Sigma(gas) by inverting the multi-freefall star formation relation, which connects the star formation rate surface density (Sigma(SFR)) with Sigma(gas) and the turbulent Mach number (M). Based on the measured range of Sigma(SFR) = 0.005-1.5M(circle dot)yr(-1) kpc(-2) and M = 18-130, we predict Sigma(gas) = 7-200M(circle dot)pc(-2) in the star-forming regions of our sample of 260 SAMI galaxies. These values are close to previously measured Sigma(gas) obtained directly with unresolved CO observations of similar galaxies at low redshift. We classify each galaxy in our sample as 'star-forming' (219) or 'composite/AGN/shock' (41), and find that in `composite/AGN/shock' galaxies the average Sigma(SFR), M and Sigma(gas) are enhanced by factors of 2.0, 1.6 and 1.3, respectively, compared to star-forming galaxies. We compare our predictions of Sigma(gas) with those obtained by inverting the Kennicutt Schmidt relation and find that our new method is a factor of 2 more accurate in predicting Sigma(gas), with an average deviation of 32 per cent from the actual Sigma(gas).

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