We use medium- and high-resolution spectroscopy of close pairs of quasars to analyze the circumgalactic medium (CGM) surrounding 32 damped Ly
We analyze the cool gas in and around 14 nearby galaxies (at
- Award ID(s):
- 2007538
- NSF-PAR ID:
- 10449353
- Publisher / Repository:
- DOI PREFIX: 10.3847
- Date Published:
- Journal Name:
- The Astrophysical Journal
- Volume:
- 954
- Issue:
- 2
- ISSN:
- 0004-637X
- Format(s):
- Medium: X Size: Article No. 115
- Size(s):
- ["Article No. 115"]
- Sponsoring Org:
- National Science Foundation
More Like this
-
more » « less
Abstract α absorption systems (DLAs). The primary quasar sightline in each pair probes an intervening DLA in the redshift range 1.6 <z abs< 3.5, such that the secondary sightline probes absorption from Lyα and a large suite of metal-line transitions (including Oi , Cii , Civ , Siii , and Siiv ) in the DLA host galaxy’s CGM at transverse distances 24 kpc ≤R ⊥≤ 284 kpc. Analysis of Lyα in the CGM sightlines shows an anticorrelation betweenR ⊥and Hi column density (N HI) with 99.8% confidence, similar to that observed around luminous galaxies. The incidences of Cii and Siii withN > 1013cm−2within 100 kpc of DLAs are larger by 2σ than those measured in the CGM of Lyman break galaxies (Cf (N CII ) > 0.89 andN HI> 1018.5cm−2show a significant degree of scatter (with metallicities/limits across the rangeiv λ 1548 and low-ionization metal species in the DLA versus CGM sightlines are strongly (>2σ ) correlated, suggesting that they trace the potential well of the host halo overR ⊥≲ 300 kpc scales. At the same time, velocity centroids for Civ λ 1548 differ in DLA versus CGM sightlines by >100 km s−1for ∼50% of velocity components, but few components have velocities that would exceed the escape velocity assuming dark matter host halos of ≥1012M ⊙. -
more » « less
Abstract The Sloan Digital Sky Survey MaNGA program has now obtained integral field spectroscopy for over 10,000 galaxies in the nearby universe. We use the final MaNGA data release DR17 to study the correlation between ionized gas velocity dispersion and galactic star formation rate, finding a tight correlation in which
σ Hα from galactic Hii regions increases significantly from ∼18–30 km s−1, broadly in keeping with previous studies. In contrast,σ Hα from diffuse ionized gas increases more rapidly from 20–60 km s−1. Using the statistical power of MaNGA, we investigate these correlations in greater detail using multiple emission lines and determine that the observed correlation ofσ Hα with local star formation rate surface density is driven primarily by the global relation of increasing velocity dispersion at higher total star formation rate, as are apparent correlations with stellar mass. Assuming Hii region models consistent with our finding thatσ [OIII ]<σ Hα <σ [O I], we estimate the velocity dispersion of the molecular gas in which the individual Hii regions are embedded, finding valuesσ Mol= 5–30 km s−1consistent with ALMA observations in a similar mass range. Finally, we use variations in the relation with inclination and disk azimuthal angle to constrain the velocity dispersion ellipsoid of the ionized gasσ z /σ r = 0.84 ± 0.03 andσ ϕ /σ r = 0.91 ± 0.03, similar to that of young stars in the Galactic disk. Our results are most consistent with the theoretical models in which turbulence in modern galactic disks is driven primarily by star formation feedback. -
more » « less
Abstract Dwarf galaxies are found to have lost most of their metals via feedback processes; however, there still lacks consistent assessment on the retention rate of metals in their circumgalactic medium (CGM). Here we investigate the metal content in the CGM of 45 isolated dwarf galaxies with
M *= 106.5–9.5M ⊙(M 200m= 1010.0–11.5M ⊙) using the Hubble Space Telescope/Cosmic Origins Spectrograph. While Hi (Lyα ) is ubiquitously detected (89%) within the CGM, we find low detection rates (≈5%–22%) in Cii , Civ , Siii , Siiii , and Siiv , largely consistent with literature values. Assuming these ions form in the cool (T ≈ 104K) CGM with photoionization equilibrium, the observed Hi and metal column density profiles can be best explained by an empirical model with low gas density and high volume filling factor. For a typical galaxy withM 200m= 1010.9M ⊙(median of the sample), our model predicts a cool gas mass ofM CGM,cool∼ 108.4M ⊙, corresponding to ∼2% of the galaxy’s baryonic budget. Assuming a metallicity of 0.3Z ⊙, we estimate that the dwarf galaxy’s cool CGM likely harbors ∼10% of the metals ever produced, with the rest either in more ionized states in the CGM or transported to the intergalactic medium. We further examine the EAGLE simulation and show that Hi and low ions may arise from a dense cool medium, while Civ arises from a diffuse warmer medium. Our work provides the community with a uniform data set on dwarf galaxies’ CGM that combines our recent observations, additional archival data and literature compilation, which can be used to test various theoretical models of dwarf galaxies. -
more » « less
Abstract The resonantly scattered Ly
α line illuminates the extended halos of neutral hydrogen in the circumgalactic medium of galaxies. We present integral field Keck Cosmic Web Imager observations of double-peaked, spatially extended Lyα emission in 12 relatively low-mass (M ⋆∼ 109M⊙)z ∼ 2 galaxies characterized by extreme nebular emission lines. Using individual spaxels and small bins as well as radially binned profiles of larger regions, we find that for most objects in the sample the Lyα blue-to-red peak ratio increases, the peak separation decreases, and the fraction of flux emerging at line center increases with radius. We use new radiative transfer simulations to model each galaxy with a clumpy, multiphase outflow with radially varying outflow velocity, and self-consistently apply the same velocity model to the low-ionization interstellar absorption lines. These models reproduce the trends of peak ratio, peak separation, and trough depth with radius, and broadly reconcile outflow velocities inferred from Lyα and absorption lines. The galaxies in our sample are well-described by a model in which neutral, outflowing clumps are embedded in a hotter, more highly ionized inter-clump medium (ICM), whose residual neutral content produces absorption at the systemic redshift. The peak ratio, peak separation, and trough flux fraction are primarily governed by the line-of-sight component of the outflow velocity, the Hi column density, and the residual neutral density in the ICM respectively. The azimuthal asymmetries in the line profile further suggest nonradial gas motions at large radii and variations in the Hi column density in the outer halos. -
more » « less
Abstract Galaxy formation and evolution are regulated by the feedback from galactic winds. Absorption lines provide the most widely available probe of winds. However, since most data only provide information integrated along the line of sight, they do not directly constrain the radial structure of the outflows. In this paper, we present a method to directly measure the gas electron density in outflows (
n e ), which in turn yields estimates of outflow cloud properties (e.g., density, volume filling factor, and sizes/masses). We also estimate the distance (r n ) from the starburst at which the observed densities are found. We focus on 22 local star-forming galaxies primarily from the COS Legacy Archive Spectroscopic SurveY (CLASSY). In half of them, we detect absorption lines from fine-structure excited transitions of Siii (i.e., Siii *). We determinen e from relative column densities of Siii and Siii *, given Siii * originates from collisional excitation by free electrons. We find that the derivedn e correlates well with the galaxy’s star formation rate per unit area. From photoionization models or assuming the outflow is in pressure equilibrium with the wind fluid, we getr n ∼ 1–2r *or ∼5r *, respectively, wherer *is the starburst radius. Based on comparisons to theoretical models of multiphase outflows, nearly all of the outflows have cloud sizes large enough for the clouds to survive their interaction with the hot wind fluid. Most of these measurements are the first ever for galactic winds detected in absorption lines and, thus, will provide important constraints for future models of galactic winds.
