Galaxy formation and evolution

Morpheus Reveals Distant Disk Galaxy Morphologies with JWST: The First AI/ML Analysis of JWST Images

(2022)

Authors:

Brant E Robertson, Sandro Tacchella, Benjamin D Johnson, Ryan Hausen, Adebusola B Alabi, Kristan Boyett, Andrew J Bunker, Stefano Carniani, Eiichi Egami, Daniel J Eisenstein, Kevin N Hainline, Jakob M Helton, Zhiyuan Ji, Nimisha Kumari, Jianwei Lyu, Roberto Maiolino, Erica J Nelson, Marcia J Rieke, Irene Shivaei, Fengwu Sun, Hannah Ubler, Christina C Williams, Christopher NA Willmer, Joris Witstok

A fresh look at AGN spectral energy distribution fitting with the XMM-SERVS AGN sample

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 515:4 (2022) 5617-5628

Authors:

Adam Marshall, Matthew W Auger-Williams, Manda Banerji, Roberto Maiolino, Rebecca Bowler

Connecting radio emission to AGN wind properties with broad absorption line quasars

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 515:4 (2022) 5159-5174

Authors:

JW Petley, LK Morabito, DM Alexander, AL Rankine, VA Fawcett, DJ Rosario, JH Matthews, TM Shimwell, A Drabent

Impact of radiation feedback on the formation of globular cluster candidates during cloud–cloud collisions

Astrophysical Journal IOP Publishing 935:1 (2022) 53

Authors:

Daniel Han, Taysun Kimm, Harley Katz, Julien Devriendt, Adrianne Slyz

Abstract:

To understand the impact of radiation feedback during the formation of a globular cluster (GC), we simulate a head-on collision of two turbulent giant molecular clouds (GMCs). A series of idealized radiation-hydrodynamic simulations is performed, with and without stellar radiation or Type II supernovae. We find that a gravitationally bound, compact star cluster of mass M_GC ∼ 10⁵ M_⊙ forms within ≈3 Myr when two GMCs with mass M_GMC = 3.6 × 10⁵ M⊙ collide. The GC candidate does not form during a single collapsing event but emerges due to the mergers of local dense gas clumps and gas accretion. The momentum transfer due to the absorption of the ionizing radiation is the dominant feedback process that suppresses the gas collapse, and photoionization becomes efficient once a sufficient number of stars form. The cluster mass is larger by a factor of ∼2 when the radiation feedback is neglected, and the difference is slightly more pronounced (16%) when extreme Lyα feedback is considered in the fiducial run. In the simulations with radiation feedback, supernovae explode after the star-forming clouds are dispersed, and their metal ejecta are not instantaneously recycled to form stars.

MIGHTEE-Hi: evolution of hi scaling relations of star-forming galaxies at z < 0.5* * released on July 29, 2022

Astrophysical Journal Letters IOP Science 935:1 (2022) L13

Authors:

F Sinigaglia, G Rodighiero, E Elson, M Vaccari, N Maddox, Bs Frank, Mj Jarvis, T Oosterloo, R Davé, M Salvato, M Baes, S Bellstedt, L Bisigello, Jd Collier, Rhw Cook, Ljm Davies, J Delhaize, Sp Driver, C Foster, S Kurapati, Cd Claudia, C Lidman, Pe Mancera Piña, Mj Meyer, Km Mogotsi, H Pan, Aa Ponomareva, I Prandoni, Sha Rajohnson, Asg Robotham, Mg Santos, S Sekhar, K Spekkens, Je Thorne, Jm van der Hulst, Oi Wong

Abstract:

We present the first measurements of H i galaxy scaling relations from a blind survey at z > 0.15. We perform spectral stacking of 9023 spectra of star-forming galaxies undetected in H i at 0.23 < z < 0.49, extracted from MIGHTEE-H i Early Science data cubes, acquired with the MeerKAT radio telescope. We stack galaxies in bins of galaxy properties (stellar mass M *, star formation rateSFR, and specific star formation rate sSFR, with sSFR ≡ M */SFR), obtaining ≳5σ detections in most cases, the strongest H i-stacking detections to date in this redshift range. With these detections, we are able to measure scaling relations in the probed redshift interval, finding evidence for a moderate evolution from the median redshift of our sample z med ∼ 0.37 to z ∼ 0. In particular, low-M * galaxies ( log 10 ( M * / M ⊙ ) ∼ 9 ) experience a strong H i depletion (∼0.5 dex in log 10 ( M H I / M ⊙ ) ), while massive galaxies ( log 10 ( M * / M ⊙ ) ∼ 11 ) keep their H i mass nearly unchanged. When looking at the star formation activity, highly star-forming galaxies evolve significantly in M H I (f H I, where f H I ≡ M H I/M *) at fixed SFR (sSFR), while at the lowest probed SFR (sSFR) the scaling relations show no evolution. These findings suggest a scenario in which low-M * galaxies have experienced a strong H i depletion during the last ∼5 Gyr, while massive galaxies have undergone a significant H i replenishment through some accretion mechanism, possibly minor mergers. Interestingly, our results are in good agreement with the predictions of the simba simulation. We conclude that this work sets novel important observational constraints on galaxy scaling relations.