CloudFlex: A Flexible Parametric Model for the Small-Scale Structure of the Circumgalactic Medium
Abstract
We present CloudFlex, a new open-source tool for predicting the absorption-line signatures of cool gas in galaxy halos with complex small-scale structure. Motivated by analyses of cool material in hydrodynamical simulations of turbulent, multiphase media, we model individual cool gas structures as assemblies of cloudlets with a power-law distribution of cloudlet mass m cl-α and relative velocities drawn from a turbulent velocity field. The user may specify α, the lower limit of the cloudlet mass distribution (m cl,min), and several other parameters that set the total mass, size, and velocity distribution of the complex. We then calculate the MgII 2796 absorption profiles induced by the cloudlets along pencil-beam lines of sight. We demonstrate that at fixed metallicity, the covering fraction of sightlines with equivalent widths W2796 < 0.3 Ang increases significantly with decreasing m cl,min, cool cloudlet number density (n cl), and cloudlet complex size. We then present a first application, using this framework to predict the projected W2796 distribution around L* galaxies. We show that the observed incidences of W2796>0.3 Ang sightlines within 10 kpc < R < 50 kpc are consistent with our model over much of parameter space. However, they are underpredicted by models with m cl,min100M and n cl0.03 cm-3, in keeping with a picture in which the inner cool circumgalactic medium (CGM) is dominated by numerous low-mass cloudlets (m cl100M) with a volume filling factor 1\%. When used to simultaneously model absorption-line datasets built from multi-sightline and/or spatially-extended background probes, CloudFlex will enable detailed constraints on the size and velocity distributions of structures comprising the photoionized CGM.
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