Slicing the cool circumgalactic medium along the major-axis of a star-forming galaxy at z = 0.7

Abstract

We present spatially-resolved echelle spectroscopy of an intervening MgII-FeII-MgI absorption-line system detected at z abs=0.73379 toward the giant gravitational arc PSZ1 G311.65-18.48. The absorbing gas is associated to an inclined disk-like star-forming galaxy, whose major axis is aligned with the two arc-segments reported here. We probe in absorption the galaxy's extended disk continuously, at ≈ 3 kpc sampling, from its inner region out to 15× the optical radius. We detect strong (W02796>0.3 A) coherent absorption along 13 independent positions at impact parameters D=0--29 kpc on one side of the galaxy, and no absorption at D=28--57 kpc on the opposite side (all de-lensed distances at z abs). We show that: (1) the gas distribution is anisotropic; (2) W02796, W02600, W02852, and the ratio W02600\!/W02796, all anti-correlate with D; (3) the W02796-D relation is not cuspy and exhibits significantly less scatter than the quasar-absorber statistics; (4) the absorbing gas is co-rotating with the galaxy out to D 20 kpc, resembling a `flat' rotation curve, but at D 20 kpc velocities decline below the expectations from a 3D disk-model extrapolated from the nebular [OII] emission. These signatures constitute unambiguous evidence for rotating extra-planar diffuse gas, possibly also undergoing enriched accretion at its edge. Arguably, we are witnessing some of the long-sought processes of the baryon cycle in a single distant galaxy expected to be representative of such phenomena.