We study the relationship between the H2 and CO abundances in simulated molecular clouds using a fully dynamical model of magnetized turbulence coupled to a detailed chemical network. We find that the CO-to-H2 conversion factor for a given molecular cloud, the so-called X-factor, is determined primarily by the mean extinction of the cloud, rather than by its metallicity. Our results explain the discrepancy observed in low metallicity systems between cloud masses derived from CO observations and other techniques such as infrared emission, and predict that CO-bright clouds in low metallicity systems should be systematically larger and/or denser than Milky Way clouds
Relating the observed CO emission from giant molecular clouds (GMCs) to the underlying H2 column den...
We examine several different simplified approaches for modelling the chemistry of CO in 3D numerical...
Carbon monoxide (CO) is widely used as a tracer of molecular hydrogen (H2) in metal-rich galaxies, b...
We investigate how the X factor, the ratio of the molecular hydrogen column density (?) to velocity-...
Characterizing the conversion factor between CO emission and column density of molecular hydrogen, X...
Theoretical and observational investigations have indicated that the abundance of carbon monoxide (C...
We present a series of numerical simulations that explore how the ‘X-factor’, XCO – the conversion f...
The properties of synthetic CO emission from 3D simulations of forming molecular clouds are studied ...
We present an analysis of giant molecular clouds (GMCs) within hydrodynamic simulations of isolated,...
We derive the CO-to-H2 conversion factor, XCO = N(H2)/ICO, across the Perseus molecular cloud on sub...
The CO–H₂ conversion factor (X_(CO); otherwise known as the X-factor) is observed to be remarkably c...
International audienceA reliable estimate of the molecular gas content in galaxies plays a crucial r...
The factor relating CO emission to molecular hydrogen column density, XCO, is still subject to uncer...
We examine the physical parameters that affect the accumulation of gas in molecular clouds to high c...
We show that the XCO factor, which converts the CO luminosity into the column density of m...
Relating the observed CO emission from giant molecular clouds (GMCs) to the underlying H2 column den...
We examine several different simplified approaches for modelling the chemistry of CO in 3D numerical...
Carbon monoxide (CO) is widely used as a tracer of molecular hydrogen (H2) in metal-rich galaxies, b...
We investigate how the X factor, the ratio of the molecular hydrogen column density (?) to velocity-...
Characterizing the conversion factor between CO emission and column density of molecular hydrogen, X...
Theoretical and observational investigations have indicated that the abundance of carbon monoxide (C...
We present a series of numerical simulations that explore how the ‘X-factor’, XCO – the conversion f...
The properties of synthetic CO emission from 3D simulations of forming molecular clouds are studied ...
We present an analysis of giant molecular clouds (GMCs) within hydrodynamic simulations of isolated,...
We derive the CO-to-H2 conversion factor, XCO = N(H2)/ICO, across the Perseus molecular cloud on sub...
The CO–H₂ conversion factor (X_(CO); otherwise known as the X-factor) is observed to be remarkably c...
International audienceA reliable estimate of the molecular gas content in galaxies plays a crucial r...
The factor relating CO emission to molecular hydrogen column density, XCO, is still subject to uncer...
We examine the physical parameters that affect the accumulation of gas in molecular clouds to high c...
We show that the XCO factor, which converts the CO luminosity into the column density of m...
Relating the observed CO emission from giant molecular clouds (GMCs) to the underlying H2 column den...
We examine several different simplified approaches for modelling the chemistry of CO in 3D numerical...
Carbon monoxide (CO) is widely used as a tracer of molecular hydrogen (H2) in metal-rich galaxies, b...