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COS-EDGES: Co-rotation and kinematic stratification of the multi-phase CGM around edge-on galaxies

Published online by Cambridge University Press:  11 September 2025

Glenn G. Kacprzak*
Affiliation:
Centre for Astrophysics and Supercomputing, Swinburne University of Technology, Hawthorn, VIC, Australia
Benjamin Oppenheimer
Affiliation:
University of Colorado, Center for Astrophysics and Space Astronomy, Boulder, CO, USA
Nikole Nielsen
Affiliation:
Centre for Astrophysics and Supercomputing, Swinburne University of Technology, Hawthorn, VIC, Australia Homer L. Dodge Department of Physics and Astronomy, The University of Oklahoma, Norman, OK, USA
Antonia Fernández-Figueroa
Affiliation:
Centre for Astrophysics and Supercomputing, Swinburne University of Technology, Hawthorn, VIC, Australia
Michael T. Murphy
Affiliation:
Centre for Astrophysics and Supercomputing, Swinburne University of Technology, Hawthorn, VIC, Australia
Rebecca Allen
Affiliation:
Centre for Astrophysics and Supercomputing, Swinburne University of Technology, Hawthorn, VIC, Australia
Tania Barone
Affiliation:
Centre for Astrophysics and Supercomputing, Swinburne University of Technology, Hawthorn, VIC, Australia
Sameer Sameer
Affiliation:
Department of Physics and Astronomy, University of Notre Dame, Notre Dame, IN, USA
Christopher W. Churchill
Affiliation:
Department of Astronomy, New Mexico State University, Las Cruces, NM, USA
Joseph Burchett
Affiliation:
Department of Astronomy, New Mexico State University, Las Cruces, NM, USA
Kaustubh R. Gupta
Affiliation:
Centre for Astrophysics and Supercomputing, Swinburne University of Technology, Hawthorn, VIC, Australia
Jane C. Charlton
Affiliation:
Department of Astronomy and Astrophysics, The Pennsylvania State University, State College, PA, USA
Caleb Platukis
Affiliation:
Department of Astronomy and Astrophysics, The Pennsylvania State University, State College, PA, USA
*
Corresponding author: Glenn Kacprzak, Email: gkacprzak@swin.edu.au.
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Abstract

We present the first results from the COS-EDGES survey, targeting the kinematic connection between the interstellar medium and multi-phase circumgalactic medium (CGM) in nine isolated, near-edge-on galaxies at $z\sim0.2$, each probed along its major axis by a background quasar at impact parameters of $D=13-38$ kpc. Using VLT/UVES and HST/COS quasar spectra, we analyse Mgi, Mgii, Hi, Cii, Ciii, and Ovi absorption relative to galaxy rotation curves from Keck/LRIS and Magellan/MagE spectra. We find that low ionisation absorption for 8/9 galaxies lies below the halo escape velocity, indicating bound inflow or recycling gas, while 6/9 galaxies have high ionisation gas reaching above the halo escape velocity, suggesting some unbound material. We find that at lower $D/R_{\textrm{vir}}$ ($0.12\leq D/R_{\textrm{vir}} \leq0.20$), over 80% of absorption in all ions lies on the side of systemic velocity matching disk rotation, and the optical-depth–weighted median velocity ($v_{abs}$) is consistent with the peak rotation speed. At higher $D/R_{\textrm{vir}}$ ($0.21\leq D/R_{\textrm{vir}} \leq0.31$), the kinematics diverge by ionisation state: For the low ionisation gas, the amount of co-rotating absorption remains above 80%, yet $v_{abs}$ drops to roughly 60% of the galaxy rotation speed. For the high ionisation gas (Ovi), only 60% of the absorption is consistent with co-rotation and $v_{abs}$ drops to 20% of the galaxy rotation speed. Furthermore, the velocity widths, corresponding to 50% of the total optical depth ($\Delta v_{50}$) for low ionisation gas is up to 1.8 times larger in the inner halo than at larger radii, while for Ciii and Ovi $\Delta v_{50}$ remains unchanged with distance. The 90% optical-depth width ($\Delta v_{90}$) shows a modest decline with radius for low ionisation gas but remains constant Ciii and Ovi. At high $D/{R}_{\textrm{vir}}$, both $\Delta v_{50}$ and $\Delta v_{90}$ increase with ionisation potential. These results suggest a radially dependent CGM kinematic structure: the inner halo hosts cool, dynamically broad gas tightly coupled to disk rotation, whereas beyond $\gtrsim 0.2 R_{\textrm{vir}}$, particularly traced by Ovi and Hi, the CGM shows weaker rotational alignment and lower relative velocity dispersion. Therefore, low-ionisation gas likely traces extended co-rotating gas, inflows and/or recycled accretion, while high-ionisation gas reflects a mixture of co-rotating, lagging, discrete collisionally ionised structures and volume-filling warm halo, indicating a complex kinematic stratification of the multi-phase CGM.

Information

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2025. Published by Cambridge University Press on behalf of Astronomical Society of Australia
Figure 0

Table 1. Columns are: (1) Galaxy name. (2) Galaxy right ascension. (3) Galaxy declination. (4) Galaxy emission-line redshift. (5) Impact parameter adopted from Huang et al. (2021). (6) Halo virial radius calculated following the formalism of Bryan & Norman (1998). (7) Ratio of the impact parameter and virial radius. (8) Logarithm of the stellar mass adopted from Huang et al. (2021). (9) Logarithm of the halo mass computed using the stellar-to-halo mass relation from Girelli et al. (2020). (10) Star formation rate from [Oii] ($\dagger$) or H$\alpha$ ($\ddagger$) emission. (11) Galaxy inclination angle. (12) Galaxy azimuthal angle where zero degrees is along the galaxy major axis.

Figure 1

Figure 1. (Left) DECaLS grz composite images of each quasar field, in which the quasar appears as a bright blue point source and the largest galaxy in the frame is the targeted foreground galaxy. The galaxies are moderately inclined and have their major axes pointed towards the quasar sightline. These galaxies were previously identified as being isolated (Huang et al. 2021). (Right) Impact parameter, D, versus the Mgii$\lambda$2796 rest-frame equivalent width, $W_r(2796)$. The blue squares are the nine galaxies examined here. The grey data are from MAGiiCAT (Nielsen et al. 2013b), where galaxies having detected Mgii absorption are presented as circles and those with upper limits on absorption are downward arrows. The solid curve is a log-linear maximum likelihood fit to the MAGiiCAT data with 1$\sigma$ uncertainties shown as dotted lines, which were adopted from Nielsen et al. (2013a).

Figure 2

Figure 2. Kinematic comparison between the galaxy ISM rotation curve for G7 and the multi-phase CGM absorption, with the quasar field image for reference. Blue circles represent the galaxy’s rotation curve, with rotation towards the quasar in the upper right quadrant. The y-axes show line of sight velocity relative to the galaxy systemic (right) and normalised by peak galaxy rotation velocity (left). The top and bottom axes indicate the impact parameter (D) and $D/{R}_{\textrm{vir}}$, respectively, with the quasar distance labelled in the figure. Absorption profiles at the quasar sightline for ions of increasing ionisation potential are shown, offset for clarity. This figure allows a direct comparison of galaxy and CGM kinematics, demonstrating that the multi-phase CGM aligns with the galaxy’s rotation direction.

Figure 3

Figure 3. Same as Figure 2 but for G8, having a $D/{R}_{\textrm{vir}} = 0.24$, with the rotation towards the quasar in the upper right quadrant. While the strongest absorption component from Mgi and Mgii are consistent with the galaxy’s rotation direction, but slower than the maximum rotation speed, absorption in the opposite direction is also observed, particularly for Ciii and Ovi.

Figure 4

Figure 4. Kinematic comparison of the multi-phase CGM absorption relative to the escape velocity for galaxies G1–G9. Galaxies are ordered in increasing $D/R_{\textrm{vir}}$ from left to right, top to bottom. Absorption features for each galaxy are shown as histograms, with the line-of-sight velocity on the y-axis and the ion name along the x-axis indicates the different ions. The black dashed lines represent the escape velocity at $R_{\textrm{vir}}$ and the grey dashed lines represent the escape velocity at projected distance D, for each galaxy. Galaxies in the figure without grey dashed lines have escape velocities at D exceeding the plotted range of $\pm320\ \text{km}\ \text{s}^{-1}$ (G2, G4, G5, and G9). The escape velocity lines allow for a comparison of the multi-phase CGM kinematics with the galaxy’s gravitational potential, where the gas may be gravitationally bound or exceed the escape velocity. For the escape velocity at $R_{\textrm{vir}}$, 8/9 systems show all of the low ionisation gas being bound to the halo while higher ionisation gas is bound to the halo for 6/9 galaxies. All of the CGM is bound at the projected distance.

Figure 5

Figure 5. Stacked Mgi, Hi, Mgii, Cii, Ciii, and Ovi absorption lines for the low $D/R_{\textrm{vir}}$ bin ($0.12\leq D/R_{\textrm{vir}}\leq0.20$). The spectra are offset along the y-axis in order to compare their kinematic structure. The x-axis shows (left) line-of-sight velocity and (right) normalised velocities relative to the maximum galaxy rotation speed. Positive velocities align with the direction of galaxy rotation towards the quasar sightline. At low $D/R_{\textrm{vir}}$, the Mgi, and Mgii are fully aligned with the direction of rotation of the galaxy, while Hi, Cii, Ciii, and Ovi have a small fraction absorption in the opposite direction of rotation.

Figure 6

Figure 6. Same as Figure 5 except the stacked spectra are now plotted for the high $D/R_{\textrm{vir}}$ bin ($0.21\leq D/R_{\textrm{vir}} \leq0.31$). In contrast to the low $D/R_{\textrm{vir}}$ subsample, Mgii and possibly Mgi have a small fraction of absorption in the opposite direction of rotation. Furthermore, most of their optical depth is located at lower velocities closer to systemic. Hi, Ciii, and Ovi exhibit a broad single absorption profile and have more absorption on the opposite side of the galaxy rotation direction.

Figure 7

Figure 7. (Left) Optical depth weighted median velocity, $v_{\textrm{abs}}$, of the bootstrapped-stacked spectra for each ion relative to the galaxy systemic velocity ($v=0$ km s$^{-1}$), where the positive values indicate gas moving in the direction of the galaxy rotation, for low and high $D/R_{\textrm{vir}}$ bins. At low $D/R_{\textrm{vir}}$, the optical depth weighted velocity for all ions is consistent with 110 km s$^{-1}$ with no apparent shift between ions. For high $D/R_{\textrm{vir}}$, the optical depth weighted velocity decreases by a factor of up to 2.75 and Ovi exhibits the largest shift. (Right) Optical depth weighted median velocity of each ion relative to the galaxy maximum normalised velocity, where the dashed line indicates the maximum rotation speed. The optical depth weighted median velocity at lower $D/R_{\textrm{vir}}$ is consistent with the maximum rotation speed of the galaxy. At higher $D/R_{\textrm{vir}}$, the optical depth weighted median velocity is lower than the rotation speed of the galaxy, with the largest difference found for Ovi.

Figure 8

Figure 8. Velocity widths corresponding to 50% ($\Delta v_{50}$) (left) and 90% ($\Delta v_{90}$) (right) of the total optical depth for the bootstrapped-stacked spectra for each ion in the low $D/R_{\textrm{vir}}$ and high $D/R_{\textrm{vir}}$ bins. Larger $\Delta v_{50}$ values are found closer to the galaxies and for more highly ionised gas, with increasing velocity width for the higher ionisation ions. The increase $\Delta v_{50}$ is shallow for gas close to galaxies (low $D/R_{\textrm{vir}}$) and more steep for gas further from galaxies (high $D/R_{\textrm{vir}}$). For the most highly ionised gas traced by Ciii and Ovi, there is no difference in $\Delta v_{50}$ with $D/R_{\textrm{vir}}$. For $\Delta v_{90}$, there is a possible shallow increase in velocity from low to high ionisation gas for low $D/R_{\textrm{vir}}$, whereas there is a steeper increase for high $D/R_{\textrm{vir}}$. Again, there is no change in $\Delta v_{90}$ for Ciii and Ovi with $D/R_{\textrm{vir}}$.

Figure 9

Figure 9. (Left) Rest-frame equivalent width co-rotation fraction (measurement adopted from Nateghi et al. 2024a, b) for both low and high $D/R_{\textrm{vir}}$ bins for Hi and the metal lines. A value of unity implies all of the absorption is consistent with the direction of rotation of the galaxy. The CGM becomes more disconnected from galaxy rotation for higher ionisation gas and with increasing $D/R_{\textrm{vir}}$; the largest change occurs for Ciii, Ovi and Hi. (Right) Adapted from Nateghi et al. (2024b), showing their distribution of the change in the co-rotation fraction as a function of ionisation potential ($(d(f_{\textrm{EWcorot}})/d{(\textrm{eV})})$), with the top x-axis showing the difference between co-rotation fractions of Mgii and Ovi: $\Delta f_{\textrm{EWcorot}}$ (Mgii – Ovi). The green line represents the average of their sample, where the distribution shows that the majority of the systems that exhibit low-ionisation gas has a higher co-rotation fraction compared to the higher-ionisation phase. The black lines indicate the slope for the low and high $D/R_{\textrm{vir}}$ bins for the galaxies presented here.

Figure 10

Figure A1. Same as Figure 2 but for G1, having a $D=21.9$ kpc and $D/{R}_{\textrm{vir}} = 0.20$ with a maximum rotation speed of $\sim110$ km s$^{-1}$ in the direction of quasar. The low ionisation absorption (Mgi, Oi, Mgii) is consistent with the galaxy’s rotation direction, with absorption velocities ranging between the galaxy systemic velocity and the maximum rotation speed. Hi, Cii, Ciii and Ovi have absorption at the maximum rotation speed of the galaxy, with a small fraction of their absorption in the opposite direction of rotation.

Figure 11

Figure A2. Same as Figure 2 but for G2, having a $D=30.4$ kpc and $D/{R}_{\textrm{vir}} = 0.21$, with a maximum rotation speed of $\sim100$ km s$^{-1}$ in the direction of quasar. The low ionisation absorption (Mgi, and Mgii) is consistent with the galaxy’s rotation direction but at velocities lower than the maximum rotation speed of the galaxy. Hi, Nii, Ciii and Ovi have a small fraction of their absorption in the opposite direction of rotation.

Figure 12

Figure A3. Same as Figure 2 but for G3, having a $D=28.4$ kpc and $D/{R}_{\textrm{vir}} = 0.31$, with a maximum rotation speed of $\sim65$ km s$^{-1}$ in the direction of quasar. The low ionisation absorption (Mgi, Mgii, Cii) is consistent with the galaxy’s rotation direction and maximum rotation speed. Hi, Ciii and Ovi have a small fraction of their absorption in the opposite direction of rotation.

Figure 13

Figure A4. Same as Figure 2 but for G4, having a $D=31.0$ kpc and $D/{R}_{\textrm{vir}} = 0.20$, with a maximum rotation speed of $\sim155$ km s$^{-1}$ in the direction of quasar. The low ionisation absorption (Mgi, Oi, Mgii, Ciii) is consistent with the galaxy’s rotation direction and slower than the maximum galaxy rotation speed. Hi, Ciii and Ovi have a small fraction of their absorption in the opposite direction of rotation.

Figure 14

Figure A5. Same as Figure 2 but for G5, having a $D=37.5$ kpc and $D/{R}_{\textrm{vir}} = 0.22$, with a maximum rotation speed of $\sim60$ km s$^{-1}$ in the direction of quasar. The low ionisation absorption (Mgi, Mgii, Ciii) is consistent with the galaxy’s rotation direction, with velocities above and below the maximum galaxy rotation speed. Hi, Ciii and Ovi have a small fraction of their absorption in the opposite direction of rotation.

Figure 15

Figure A6. Same as Figure 2 but for G6, having a $D=25.3$ kpc and $D/{R}_{\textrm{vir}} = 0.24$, with a maximum rotation speed of $\sim75$ km s$^{-1}$ in the direction of quasar. The bulk of the low ionisation absorption (Mgi, Mgii, Ciii) is consistent with the galaxy’s rotation direction, with velocities at and below the maximum galaxy rotation speed. Some low ionisation absorption is also found in the opposite direction of rotation. Hi, Ciii and Ovi have a small fraction of their absorption in the opposite direction of rotation.

Figure 16

Figure A7. Same as Figure 2 but for G9, having a $D=31.6$ kpc and $D/{R}_{\textrm{vir}} = 0.19$, with a maximum rotation speed of $\sim100$ km s$^{-1}$ in the direction of quasar. All of the ions have velocities consistent with the galaxy’s rotation direction.