Galaxy formation and evolution

Creating halos with autoregressive multistage networks

Physical Review D American Physical Society (APS) 112:10 (2025) 103503

Authors:

Shivam Pandey, Chirag Modi, Benjamin D Wandelt, Deaglan J Bartlett, Adrian E Bayer, Greg L Bryan, Matthew Ho, Guilhem Lavaux, T Lucas Makinen, Francisco Villaescusa-Navarro

The GECKOS Survey: revealing the formation history of a barred galaxy via structural decomposition and resolved spectroscopy

(2025)

Authors:

A Fraser-McKelvie, DA Gadotti, F Fragkoudi, C de Sá-Freitas, M Martig, M Bureau, T Davis, R Elliott, E Emsellem, D Fisher, MR Hayden, J van de Sande, AB Watts

Warped Disk Galaxies. II. From the Cosmic Web to the Galactic Warp

The Astrophysical Journal American Astronomical Society 993:2 (2025) 205

Authors:

Woong-Bae G Zee, S Lyla Jung, Sanjaya Paudel, Suk-Jin Yoon

Abstract:

Galactic warps are common in disk galaxies. While often attributed to galaxy–galaxy tides, a nonspherical dark matter halo has also been proposed as a driver of disk warping. We investigate links among warp morphology, satellite distribution, and large-scale structure using the Sloan Digital Sky Survey catalog of warped disks compiled by W.-B. G. Zee et al. Warps are classified into 244 S- and 127 U-types, hosting 1373 and 740 satellites, respectively, and are compared to an unwarped control matched in stellar mass, redshift, and local density. As an indirect, population-level proxy for the host halo’s shape and orientation, we analyze the stacked spatial distribution of satellites. Warped hosts show a significant anisotropy: an excess at 45° < ϕ < 90° (measured from the host major axis), peaking at P(ϕ) ≃ 0.003, versus nearly isotropic controls. Satellites of S-type warps preferentially align with the nearest cosmic filament, whereas those of U-type warps are more often perpendicular. The incidence of warps increases toward filaments (rfila < 4 Mpc h−1), while the number of satellites around warped hosts remains approximately constant with filament distance, indicating a direct influence of the large-scale environment. We discuss possible links between galactic warps and the cosmic web, including anisotropic tidal fields and differences in evolutionary stage.

Black hole merger rates in AGN: contribution from gas-captured binaries

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) (2025) staf1896

Authors:

Connar Rowan, Henry Whitehead, Bence Kocsis

Abstract:

Abstract Merging black hole (BH) binaries in AGN discs formed through two-body scatterings via the “gas-capture” process may explain a significant fraction of BH mergers in AGN and a non-negligible contribution to the observed rate from LIGO-VIRGO-KAGRA. We perform Monte Carlo simulations of binary BH formation, evolution and mergers across the observed AGN mass function using a novel physically motivated treatment for the gas-capture process derived from hydrodynamical simulations of BH-BH encounters in AGN. Our models suggest that gas-captured binaries could result in merger rates of 0.73 − 7.1Gpc−3yr−1. Mergers from AGN are dominated by AGN with supermassive BH masses of ∼107M⊙, with 90 % of mergers occurring in the range ∼106M⊙ − 108M⊙. The merging mass distribution is flatter than the initial BH mass power law by a factor Δξ = 1.1 − 1.2, as larger BHs align with the disc and form binaries more efficiently. Similarly, the merging mass ratio distribution is flatter, therefore the AGN channel could explain high mass and unequal mass ratio detections such as GW190521 and GW190814. Using a simpler dynamical friction treatment for the binary formation process, the results are similar, where the primary bottleneck is the alignment time with the disc. The most influential parameters are the anticipated number of BHs and their mass function. Given the many uncertainties that remain in the AGN channel, we expect the true uncertainty extends beyond our predicted rates. Nonetheless, we conclude that AGN remain an important channel for consideration, particularly for gravitational wave detections involving one or two high mass BHs.

Shock-driven heating in the circumnuclear star-forming regions of NGC 7582: Insights from JWST NIRSpec and MIRI/MRS spectroscopy

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) (2025) staf1887

Authors:

Oscar Veenema, Niranjan Thatte, Dimitra Rigopoulou, Ismael García-Bernete, Almudena Alonso-Herrero, Anelise Audibert, Enrica Bellocchi, Andrew J Bunker, Steph Campbell, Francoise Combes, Ric I Davies, Daniel Delaney, Fergus Donnan, Federico Esposito, Santiago García-Burillo, Omaira Gonzalez Martin, Laura Hermosa Muñoz, Erin KS Hicks, Sebastian F Hoenig, Nancy A Levenson, Chris Packham, Miguel Pereira-Santaella, Cristina Ramos Almeida, Claudio Ricci, Rogemar A Riffel, David Rosario, Lulu Zhang

Abstract:

Abstract We present combined JWST NIRSpec and MIRI/MRS integral field spectroscopy data of the nuclear and circumnuclear regions of the highly dust obscured Seyfert 2 galaxy NGC 7582, which is part of the sample of AGN in the Galaxy Activity, Torus and Outflow Survey (GATOS). Spatially resolved analysis of the pure rotational H2 lines (S(1)-S(7)) reveals a characteristic power-law temperature distribution in different apertures, with the two prominent southern star-forming regions exhibiting unexpectedly high molecular gas temperatures, comparable to those in the AGN powered nuclear region. We investigate potential heating mechanisms including direct AGN photoionisation, UV fluorescent excitation from young star clusters, and shock excitation. We find that shock heating gives the most plausible explanation, consistent with multiple near- and mid-IR tracers and diagnostics. Using photoionisation models from the PhotoDissociation Region Toolbox, we quantify the ISM conditions in the different regions, determining that the southern star-forming regions have a high density (nH ∼ 105 cm−3) and are irradiated by a moderate UV radiation field (G0 ∼ 103 Habing). Fitting a suite of Paris-Durham shock models to the rotational H2 lines, as well as rovibrational 1-0 S(1), 1-0 S(2), and 2-1 S(1) H2 emission lines, we find that a slow (vs ∼ 10 km/s) C-type shock is likely responsible for the elevated temperatures. Our analysis loosely favours local starburst activity as the driver of the shocks and circumnuclear gas dynamics in NGC 7582, though the possibility of an AGN jet contribution cannot be excluded.