Does circumgalactic OVI trace low-pressure gas beyond the accretion shock? Clues from HI and low-ion absorption, line kinematics, and dust extinction

TL;DR

This study investigates whether OVI absorption around galaxies traces low-pressure, cool gas beyond the accretion shock, using multiple observables to distinguish between high-pressure and low-pressure gas scenarios.

Contribution

The paper provides evidence that OVI traces low-pressure, equilibrium gas beyond the accretion shock, challenging the high-pressure cooling gas model.

Findings

OVI correlates with impact parameter indicating outer halo origin.

Low-pressure scenario explains observations with a single phase in equilibrium.

Predicted bimodality in absorption ratios at ~100 kpc due to pressure jump.

Abstract

Large OVI columns are observed around star-forming, low-redshift ~L* galaxies, with a dependence on impact parameter indicating that most O^5+ particles reside beyond half the halo virial radius (>~100 kpc). In order to constrain the nature of the gas traced by OVI, we analyze additional observables of the outer halo, namely HI to OVI column ratios of 1-10, an absence of low-ion absorption, a mean differential extinction of E(B-V)~10^-3, and a linear relation between OVI column and velocity width. We contrast these observations with two physical scenarios: (1) OVI traces high-pressure (~30 cm^-3 K) collisionally-ionized gas cooling from a virially-shocked phase, and (2) OVI traces low-pressure (<~1 cm^-3 K) gas beyond the accretion shock, where the gas is in ionization and thermal equilibrium with the UV background. We demonstrate that the high-pressure scenario requires multiple gas phases to explain the observations, and a large deposition of energy at >~100 kpc to offset the energy radiated by the cooling gas. In contrast, the low-pressure scenario can explain all considered observations with a single gas phase in thermal equilibrium, provided that the baryon overdensity is comparable to the dark-matter overdensity, and that the gas is enriched to >~Z_sun/3 with an ISM-like dust-to-metal ratio. The low-pressure scenario implies that OVI traces a cool flow with mass flow rate of ~5 M_sun yr^-1, comparable to the star formation rate of the central galaxies. The OVI line widths are consistent with the velocity shear expected within this flow. The low-pressure scenario predicts a bimodality in absorption line ratios at ~100 kpc, due to the pressure jump across the accretion shock.