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1. The Cosmic Ultraviolet Baryon Survey (CUBS) – VI. Connecting physical properties of the cool circumgalactic medium to galaxies at z ≈ 1

   https://doi.org/10.1093/mnras/stad1886  

   Qu, Zhijie; Chen, Hsiao-Wen; Rudie, Gwen_C; Johnson, Sean_D; Zahedy, Fakhri_S; DePalma, David; Boettcher, Erin; Cantalupo, Sebastiano; Chen, Mandy_C; Cooksey, Kathy_L; et al (June 2023, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT This paper presents a newly established sample of 19 unique galaxies and galaxy groups at redshift z = 0.89–1.21 in six QSO fields from the Cosmic Ultraviolet Baryon Survey (CUBS), designated as the CUBSz1 sample. In this sample, nine galaxies or galaxy groups show absorption features, while the other 10 systems exhibit 2σ upper limits of $$\log N (\rm{He\,{\small I}})/\mbox{$${\rm cm^{-2}}$$}\lesssim 13.5$$ and $$\log N (\rm{O\,{\small V}})/\mbox{$${\rm cm^{-2}}$$}\lesssim 13.3$$. Environmental properties of the galaxies, including galaxy overdensities, the total stellar mass and gravitational potential summed over all neighbours, and the presence of local ionizing sources, are found to have a significant impact on the observed CGM absorption properties. Specifically, massive galaxies and galaxies in overdense regions exhibit a higher rate of incidence of absorption. The CGM absorption properties in galaxy groups appear to be driven by the galaxy closest to the QSO sightline, rather than by the most massive galaxy or by mass-weighted properties. We introduce a total projected gravitational potential ψ, defined as −ψ/G = ∑Mhalo/dproj summed over all group members, to characterize the galaxy environment. This projected gravitational potential correlates linearly with the maximum density detected in each sightline (i.e. a power-law slope of $$0.95_{-0.14}^{+0.15}$$), consistent with higher pressure gas being confined in deeper gravitational potential wells. In addition, we find that the radial profile of cool gas density exhibits a decline from the inner regions to the outskirts, and the amplitude is consistent with the cool gas being in pressure balance with the hot halo. Finally, we note that the ionizing flux from nearby galaxies can elevate the N(H i)/N(He i) ratio, which provides a unique diagnostic of possible local sources contributing to the ionizing radiation field. 

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2. Turbulence-dominated CGM: the origin of UV absorbers with equivalent widths of ∼1 Å

   https://doi.org/10.1093/mnras/staf1516  

   Kakoly, Aharon; Stern, Jonathan; Faucher-Giguère, Claude-André; Fielding, Drummond_B; Goldner, Roy; Sun, Guochao; Hummels, Cameron_B (September 2025, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT Theoretical arguments and observations suggest that in massive haloes ($$>10^{12}\, {\rm M}_\odot$$), the circumgalactic medium (CGM) is dominated by a ‘hot’ phase with gas temperature near the virial temperature ($$T\approx T_{\rm vir}$$) and a quasi-hydrostatic pressure profile. Lower-mass haloes are however unlikely to be filled with a similar quasi-static hot phase, due to rapid radiative cooling. Using the FIRE (Feedback In Realistic Environment) cosmological zoom simulations, we demonstrate that the hot phase is indeed subdominant at inner radii ($$\lesssim 0.3 R_{\rm vir}$$) of $$\lesssim 10^{12}\, {\rm M}_\odot$$ haloes, and the inner CGM is instead filled with $$T\ll T_{\rm vir}$$ gas originating in outflows and inflows, with a turbulent velocity comparable to the halo virial velocity. The turbulent velocity thus exceeds the mass-weighted sound speed in the inner CGM, and the turbulence is supersonic. UV absorption features from such CGM trace the wide lognormal density distributions of the predominantly cool and turbulent volume-filling phase, in contrast with tracing localized cool ‘clouds’ embedded in a hot medium. We predict equivalent widths of $$W_\lambda \sim 2\lambda v_{\rm c}/c\sim 1$$Å for a broad range of strong UV and EUV transitions (Mg ii, C ii, C iv, Si ii–iv, O iii–v) in sightlines through inner CGM dominated by turbulent pressure of $$\lesssim L^\star$$ galaxies at redshifts $$0\le z\lesssim 2$$, where $$\lambda$$ is the transition wavelength, $$v_{\rm c}$$ is the circular velocity, and c is the speed of light. Comparison of our predictions with observational constraints suggests that star forming $$\lesssim$$ $$L^\star$$ and dwarf galaxies are generally dominated by turbulent pressure in their inner CGM, rather than by thermal pressure. The inner CGM surrounding these galaxies is thus qualitatively distinct from that around quenched galaxies and massive discs such as the Milky-Way and M31, in which thermal pressure likely dominates. 

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3. Dissecting a 30 kpc galactic outflow at z ~ 1.7

   https://doi.org/10.1093/mnras/stad3004  

   Shaban, Ahmed; Bordoloi, Rongmon; Chisholm, John; Rigby, Jane R.; Sharma, Soniya; Sharon, Keren; Tejos, Nicolas; Bayliss, Matthew B.; Barrientos, L. Felipe; Lopez, Sebastian; et al (October 2023, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT We present the spatially resolved measurements of a cool galactic outflow in the gravitationally lensed galaxy RCS0327 at z ≈ 1.703 using VLT/MUSE IFU observations. We probe the cool outflowing gas, traced by blueshifted Mg ii and Fe ii absorption lines, in 15 distinct regions of the same galaxy in its image-plane. Different physical regions, 5 – 7 kpc apart within the galaxy, drive the outflows at different velocities (Vout ∼ −161 to −240 km s−1), and mass outflow rates ($$\dot{M}_{out} \sim 183$$ – 527 $${\rm M}_{\odot }\, \mathrm{yr}^{-1}$$). The outflow velocities from different regions of the same galaxy vary by 80 km s−1, which is comparable to the variation seen in a large sample of star-burst galaxies in the local universe. Using multiply lensed images of RCS0327, we probe the same star-forming region at different spatial scales (0.5–25 kpc2), we find that outflow velocities vary between ∼ −120 and −242 km s−1, and the mass outflow rates vary between ∼37 and 254 $${\rm M}_{\odot }\, \mathrm{yr}^{-1}$$. The outflow momentum flux in this galaxy is ≥ 100% of the momentum flux provided by star formation in individual regions, and outflow energy flux is ≈ 10% of the total energy flux provided by star formation. These estimates suggest that the outflow in RCS0327 is energy driven. This work shows the importance of small scale variations of outflow properties due to the variations of local stellar properties of the host galaxy in the context of galaxy evolution. 

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4. Mass and Metal in Motion; The Gas Dynamics of IllustrisTNG Halos

   Morgan, J; Bailin, J (February 2025, Bulletin of the American Astronomical Society)

   The circumgalactic medium (CGM) is a known reservoir of metals and star forming fuel. Most baryons in the universe are in the CGM or ICM. The baryon cycle- how metals reach the CGM from the inner regions of the galaxy and how gas from the CGM replenishes star forming activity in the inner regions- is an essential question in galaxy evolution. We seek to illuminate these processes by analyzing 2770 isolated halos in the IllustrisTNG simulation. This sample is divided into different classes of galaxy based star forming and AGN feedback, and morphology. By stacking halos of similar mass and history, we can identify correlations between galaxy history and the properties and dynamics of the surrounding gas. 

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5. A complete census of circumgalactic Mg  ii at redshift z ≲ 0.5

   https://doi.org/10.1093/mnras/stab360  

   Huang, Yun-Hsin; Chen, Hsiao-Wen; Shectman, Stephen A; Johnson, Sean D; Zahedy, Fakhri S; Helsby, Jennifer E; Gauthier, Jean-René; Thompson, Ian B (February 2021, Monthly Notices of the Royal Astronomical Society)

   null (Ed.)

   ABSTRACT This paper presents a survey of Mg ii absorbing gas in the vicinity of 380 random galaxies, using 156 background quasi-stellar objects (QSOs) as absorption-line probes. The sample comprises 211 isolated (73 quiescent and 138 star-forming galaxies) and 43 non-isolated galaxies with sensitive constraints for both Mg ii absorption and H α emission. The projected distances span a range from d = 9 to 497 kpc, redshifts of the galaxies range from z = 0.10 to 0.48, and rest-frame absolute B-band magnitudes range from MB = −16.7 to −22.8. Our analysis shows that the rest-frame equivalent width of Mg ii, Wr(2796), depends on halo radius (Rh), B-band luminosity(LB), and stellar mass (Mstar) of the host galaxies, and declines steeply with increasing d for isolated, star-forming galaxies. At the same time, Wr(2796) exhibits no clear trend for either isolated, quiescent galaxies or non-isolated galaxies. In addition, the covering fraction of Mg ii absorbing gas 〈κ〉 is high with 〈κ〉 ≳ 60 per cent at <40 kpc for isolated galaxies and declines rapidly to 〈κ〉 ≈ 0 at d ≳ 100 kpc. Within the gaseous radius, the incidence of Mg ii gas depends sensitively on both Mstar and the specific star formation rate inferred from H α. Different from what is known for massive quiescent haloes, the observed velocity dispersion of Mg ii absorbing gas around star-forming galaxies is consistent with expectations from virial motion, which constrains individual clump mass to $$m_{\rm cl} \gtrsim 10^5 \, \rm M_\odot$$ and cool gas accretion rate of $$\sim 0.7\!-\!2 \, \mathrm{ M}_\odot \, \rm yr^{-1}$$. Finally, we find no strong azimuthal dependence of Mg ii absorption for either star-forming or quiescent galaxies. Our results demonstrate that multiple parameters affect the properties of gaseous haloes around galaxies and highlight the need of a homogeneous, absorption-blind sample for establishing a holistic description of chemically enriched gas in the circumgalactic space. 

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