Misty, patchy, and turbulent: constraining the cold circumgalactic medium with mCC

Abstract: The circumgalactic medium (CGM) is the largest baryon reservoir around galaxies, but its extent, mass, and temperature distribution remain uncertain. We propose that cold gas in the CGM resides primarily in $\sim 100 \hbox{--} 10^4$ cloud complexes (CCs), each containing a mist of tiny cold cloudlets dispersed in a warm/hot medium ($\sim 10^5 \hbox{--} 10^6$~K). Modeling CCs as uniform and misty simplifies the calculation of observables like ion absorption columns compared to resolving tiny individual cloudlets. Using Monte Carlo simulations, we explore how CC properties affect the observed spread in column densities. A power-law distribution of CCs ($dN_{\rm CC}/dR \propto R^{-1.2}$) reproduces MgII equivalent width (EW) and column density distribution trends with impact parameter ($R_\perp$). We show that the area-averaged MgII column density, combined with the covering fraction of CCs, provides a robust proxy for estimating the cold CGM mass, independent of other model parameters. Modeling individual CCs demonstrates that turbulent broadening blends cloudlet absorption lines, allowing CCs to approximate the observational effects of their constituent cloudlets analytically. Direct simulations of cloudlets within multiple CCs confirm the computational challenges of fully resolving the mist-like structure. Comparing modeled MgII absorption with observations, we estimate the cold CGM mass of Milky Way-like galaxies to be $\sim 10^{10} \, M_\odot$, about $10\%$ of the total CGM mass. This work provides a practical framework for connecting CGM models with observations, shedding light on the cold gas distribution in galaxy halos and its role in the galactic baryon cycle.