On the Size and Mass of Photo-ionized Clouds in Extended Spiral Galaxy Halos

TL;DR

This study investigates the size and mass of circum-galactic medium clouds in a nearby galaxy's halo, revealing they are large and massive, with implications for understanding galaxy environments.

Contribution

The paper provides new observational constraints on the size and mass of CGM clouds around a typical late-type galaxy, using multiple sight lines and photo-ionization modeling.

Findings

CGM clouds have minimum sizes of 10-23 kpc.

Masses of these clouds are at least 10^6 solar masses.

Clouds are located at 0.4-0.5 R_vir from the galaxy.

Abstract

The size and mass of two circum-galactic medium (CGM) clouds in the halo (impact parameter = 65 kpc) of a nearby late-type galaxy, MGC-01-04-005 ($cz = 1865$ km/s), are investigated using a close triplet of QSO sight lines (the "LBQS Triplet"; Crighton et al. 2010). Far ultraviolet spectra obtained with the Cosmic Origins Spectrograph (COS) aboard the Hubble Space Telescope (HST) find two velocity components in Lyman $\alpha$ at $\sim1830$ and 1900 km/s in two of these sight lines, requiring minimum transverse cloud sizes of $\geq10$ kpc. A plausible, but not conclusive, detection of CIV 1548 \AA\ absorption at the higher velocity in the third sight line suggests an even larger lower limit of $\geq23$ kpc for that cloud. Using various combinations of constraints, including photo-ionization modeling for one absorber, lower limits on masses of these two clouds of $\geq10^6$ M_Sun are obtained. Ground-based imaging and long-slit spectroscopy of MCG -01-04-005 obtained at the Apache Point Observatory (APO) 3.5m telescope find it to be a relatively normal late-type galaxy with a current star formation rate (SFR) of $\sim0.01$ M_Sun per year. Galaxy Evolution Explorer (GALEX) photometry finds an SFR only a few times higher over the last $10^8$ yrs. We conclude that the CGM clouds probed by these spectra are typical in being at impact parameters of 0.4-0.5 R_vir from a rather typical, non-starbursting late-type galaxy so that these size and mass results should be generic for this class. Therefore, at least some CGM clouds are exceptionally large and massive.