The MAGPI Survey: the evolution and drivers of gas turbulence in intermediate-redshift galaxies

ABSTRACT We measure the ionized gas velocity dispersions of star-forming galaxies in the MAGPI survey ($z\sim 0.3$) and compare them with galaxies in the SAMI ($z\sim 0.05$) and KROSS ($z\sim 1$) surveys to investigate how the ionized gas velocity dispersion evolves. For the first time, we use a con...

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Bibliographic Details
Published in:Monthly notices of the Royal Astronomical Society 2024-09, Vol.533 (4), p.3878-3892
Main Authors: Mai, Yifan, Croom, Scott M, Wisnioski, Emily, Vaughan, Sam P, Varidel, Mathew R, Battisti, Andrew J, Mendel, J Trevor, Mun, Marcie, Tsukui, Takafumi, Foster, Caroline, Harborne, Katherine E, Lagos, Claudia D P, Wang, Di, Bellstedt, Sabine, Bland-Hawthorn, Joss, Colless, Matthew, D’Eugenio, Francesco, Grasha, Kathryn, Peng, Yingjie, Santucci, Giulia, Sweet, Sarah M, Thater, Sabine, Valenzuela, Lucas M, Ziegler, Bodo
Format: Article
Language:English
Subjects:
Astronomical models
Correlation
Emission analysis
Feedback
Galactic rotation
Galaxies
Gravitational instability
Motion stability
Physical properties
Red shift
Star formation
Stars & galaxies
Stellar kinematics
Turbulence
Velocity
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Summary:ABSTRACT We measure the ionized gas velocity dispersions of star-forming galaxies in the MAGPI survey ($z\sim 0.3$) and compare them with galaxies in the SAMI ($z\sim 0.05$) and KROSS ($z\sim 1$) surveys to investigate how the ionized gas velocity dispersion evolves. For the first time, we use a consistent method that forward models galaxy kinematics from $z=0$ to $z=1$. This method accounts for spatial substructure in emission line flux and beam smearing. We investigate the correlation between gas velocity dispersion and galaxy properties to understand the mechanisms that drive gas turbulence. We find that in both MAGPI and SAMI galaxies, the gas velocity dispersion more strongly correlates with the star-formation rate surface density ($\Sigma _{\rm SFR}$) than with a variety of other physical properties, and the average gas velocity dispersion is similar, at the same $\Sigma _{\rm SFR}$, for SAMI, MAGPI, and KROSS galaxies. The results indicate that mechanisms related to $\Sigma _{\rm SFR}$ could be the dominant driver of gas turbulence from $z\sim 1$ to $z\sim 0$, for example, stellar feedback and/or gravitational instability. The gas velocity dispersion of MAGPI galaxies is also correlated with the non-rotational motion of the gas, illustrating that in addition to star-formation feedback, gas transportation and accretion may also contribute to the gas velocity dispersion for galaxies at $z\sim 0.3$. KROSS galaxies only have a moderate correlation between gas velocity dispersion and $\Sigma _{\rm SFR}$ and a higher scatter of gas velocity dispersion with respect to $\Sigma _{\rm SFR}$, in agreement with the suggestion that other mechanisms, such as gas transportation and accretion, are relatively more important at higher redshift galaxies.
ISSN:0035-8711
1365-2966
DOI:10.1093/mnras/stae2033