Galaxy formation and evolution

MIGHTEE: The evolving radio luminosity functions of star-forming galaxies to z ∼ 4.5 and the cosmic history of star formation

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) (2026) stag616

Authors:

Nijin J Thykkathu, Matt J Jarvis, Imogen H Whittam, CL Hale, AM Matthews, I Heywood, Eliab Malefahlo, RG Varadaraj, N Stylianou, Chris Pearson, Nick Seymour, Mattia Vaccari

Abstract:

Abstract A key question in extragalactic astronomy is how the star-formation rate density (SFRD) evolves over cosmic time. A powerful way of addressing this question is using radio-continuum observations, where the radio waves are unaffected by dust and are able to reach sufficient resolution to resolve individual galaxies. We present an investigation of the 1.4 GHz radio luminosity functions (RLFs) of star-forming galaxies (SFGs) and Active Galactic Nuclei (AGN) using deep radio continuum observations in the COSMOS and XMM–LSS fields, covering a combined area of ∼4 deg2. These data enable the most accurate measurement of the evolution in the SFRD from mid-frequency radio continuum observations. We model the total RLF as the sum of evolving SFG and AGN components, negating the need for individual source classification. We find that the SFGs have systematically higher space densities at fixed luminosity than found in previous radio studies, but consistent with more recent studies with MeerKAT. We attribute this to the excellent low-surface brightness sensitivity of MeerKAT. We then determine the evolution of the SFRD. Adopting the far-infrared – radio correlation results in a significantly higher SFRD at z > 1, compared to combined UV and far-infrared measurements. However, using more recent relations for the correlation between star-formation rate and radio luminosity, based on full spectral energy distribution modelling, can resolve this apparent discrepancy. Thus radio observations provide a powerful method of determining the total SFRD, in the absence of dust-sensitive far-infrared data.

Diversity of SEDs among the star-forming regions in NGC 1365

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 547:4 (2026) stag266

Authors:

Stephen Hannon, Eva Schinnerer, Bradley C Whitmore, Hamid Hassani, Daizhong Liu, David A Thilker, Jessica Sutter, Janice C Lee, Jimena Rodriguez, Thomas G Williams, Médéric Boquien, Daniel A Dale, Erik Rosolowsky, Ralf S Klessen, Aida Wofford, Kiana F Henny, Kathryn Grasha, Rémy Indebetouw, Kathryn Kreckel

Abstract:

Abstract Studying samples of young star-forming regions allows us to statistically examine the evolution of their natal gas and dust along with the associated timescales in the volatile early stages of their lives. With the PHANGS survey data, we analyze the diversity of spectral energy distributions (SEDs) for the rich sample of massive star-forming regions found in NGC 1365. By combining unique detections across a variety of datasets from HST, JWST, and ALMA images, we produce a catalog of 85 star-forming regions located in the central starbursting region of NGC 1365. Prior to analysis, we observe clear saturation effects in our four JWST/MIRI images, and implement a saturation-correction method which allows us to recover data for 23 of 32 saturation-affected regions in these images. We then perform photometry in 13 HST & JWST images which are convolved to match the resolution of MIRI/F2100W (~64pc), allowing us to probe star clusters as well as their immediate surroundings. Upon deriving their properties from SED-fitting using CIGALE, we observe that regions selected with progressively redder wavebands are younger and generally more reddened. We also identify three SED features correlated with age: 1) sources with a positive near-infrared slope ((F300W+F360M)/(2×F200W)) are by median half the age of those with negative near-infrared slopes; turnover occurs around 6 Myr, 2) the relative strength of dust emission (F2100W/F200W) and 3) PAH emission (F335M/F300M) both show that larger such ratios correlate with younger ages. Considering our working resolution, these features are robust to the inclusion of nearby emission surrounding star clusters.

JWST observes the assembly of a massive galaxy at z ∼ 4

The Open Journal of Astrophysics Maynooth University 9 (2026)

Authors:

Aayush Saxena, Roderik A Overzier, Catarina Aydar, Jianwei Lyu, George H Rieke, Victoria Reynaldi, Montserrat Villar-Martín, Krisztina Éva Gabányi, Kenneth J Duncan, Sándor Frey, Andrew Humphrey, George Miley, Laura Pentericci, Krisztina Perger, Huub Röttgering, Philip Best, Sarah EI Bosman, Gyorgy Mező, Masafusa Onoue, Zsolt Paragi, Bram Venemans

Abstract:

We present JWST observations of the radio galaxy TGSSJ1530+1049, spectroscopically confirmed at $z=4.0$ . NIRCam images and NIRSpec/IFU spectroscopy ( $R=2700$ ) show that TGSSJ1530+1049 is part of one of the densest-known structures of continuum and line-emitting objects found at these redshifts. NIRCam images show a number of distinct continuum objects and evidence of interactions traced by diffuse emission, and the NIRSpec IFU cube reveals further strong line emitting regions. We identify six continuum and four additional strong Halpha emitting sources with weaker or no underlying continuum within the 3’‘x3’’ IFU field. From spatial alignment with high-resolution radio data and emission line profiles, the radio AGN host galaxy is clearly identified. The bright Halpha emission (but not the optical components) is distributed remarkably linearly along the radio axis, suggestive of a biconical illumination zone by a central obscured AGN. The emission line kinematics indicate jet-gas interactions on scales of a few kpc. However, due to large relative velocities and presence of underlying continuum, the alignment with the radio structure appears to be, at least partly, caused by a particular configuration of interacting galaxies. At least four objects within a 10x10 (projected) kpc area which includes the radio source have high stellar masses (log( $M_{\star }/M_{\odot })>10.3$ ) and star formation rates in the range 70-163 $M_{\odot }$ yr. Using a stellar mass-based analysis, we predict a total dark matter halo mass of $\approx {10}^{13}{M}_{\odot }$ . Based on the physical separations and velocity differences between the galaxies, it is expected that these galaxies will merge to form a massive galaxy within a few Gyr. The system qualitatively resembles the forming brightest cluster galaxies in cosmological simulations that form early through a rapid succession of mergers.

An OASIS of Lyman-$α$ within a neutral intergalactic desert: reaffirmed line and blue continuum reveal efficient ionising agents at $z = 13$

(2026)

Authors:

Joris Witstok, Stefano Carniani, Peter Jakobsen, Andrew J Bunker, Alex J Cameron, Francesco D'Eugenio, Kevin Hainline, Jakob M Helton, Tobias J Looser, Pierluigi Rinaldi, Brant Robertson, William M Baker, Stéphane Charlot, Benjamin D Johnson, Gareth C Jones, Nimisha Kumari, Roberto Maiolino, Jan Scholtz, Sandro Tacchella, Christopher NA Willmer, Chris Willott, Zihao Wu

WISDOM Project – XXVIII. Molecular gas measurement of the supermassive black hole mass of the galaxy NGC 1387

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) (2026) stag546

Authors:

Pandora Dominiak, Martin Bureau, Fu-Heng Liang, Michele Cappellari, Timothy A Davis, Federico Lelli, Ilaria Ruffa, Thomas G Williams, Hengyue Zhang

Abstract:

Abstract Supermassive black hole (SMBH) masses can be measured using molecular gas kinematics. Here we present high angular resolution (0.12 arcsec or ≈11 pc) Atacama Large Millimeter/submillimeter Array observations of the 12CO(2–1) line emission of the early-type galaxy NGC 1387. The observations reveal a face-on, regularly-rotating central molecular gas disc with a diameter of ≈18 arcsec (≈1.7 kpc) and a central depression slightly larger than the SMBH sphere of influence. We forward model the CO data cube in a Bayesian framework with the Kinematic Molecular Simulation code, and use Hubble Space Telescope data to constrain the stellar gravitational potential contribution to the molecular gas kinematics. We infer a SMBH mass of $1.10^{+1.71}_{-0.95}[\textrm{stat},3\sigma ]^{+2.45}_{-1.09}[\textrm{sys}]\times 10^8$ M⊙ and a F160W-filter stellar mass-to-light ratio of $0.90^{+0.44}_{-0.35}[\textrm{stat}, 3\sigma ]^{+0.46}_{-0.36}[\textrm{sys}]$ M⊙/L⊙, F160W. This SMBH mass is consistent with the SMBH mass – stellar velocity dispersion relation.