The Square Kilometre Array (SKA)

A novel Bayesian approach for decomposing the radio emission of quasars – II. Link between quasar radio emission and black hole mass

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 537:2 (2025) 858-875

Authors:

B-H Yue, KJ Duncan, PN Best, MI Arnaudova, LK Morabito, JW Petley, HJA Röttgering, S Shenoy, DJB Smith

Abstract:

ABSTRACT Whether the mass of supermassive black hole ($M_\mathrm{BH}$) is directly linked to the quasar radio luminosity remains a long-debated issue, and understanding the role of $M_\mathrm{BH}$ in the evolution of quasars is pivotal to unveiling the mechanism of active galactic nucleus (AGN) feedback. In this work, based on a two-component Bayesian model, we examine how $M_\mathrm{BH}$ affects the radio emission from quasars, separating the contributions from host galaxy star formation (SF) and AGN activity. By modelling the radio flux density distribution of Sloan Digital Sky Survey quasars from the LOFAR Two-metre Sky Survey Data Release 2, we find no correlation between $M_\mathrm{BH}$ and star formation rate (SFR) at any mass for quasars at a given redshift and bolometric luminosity. The same holds for AGN activity across most $M_\mathrm{BH}$ values; however, quasars with the top 20 per cent most massive supermassive black holes (SMBHs) are two to three times more likely to host strong radio jets than those with lower mass SMBHs at similar redshift and luminosity. We suggest defining radio quasar populations by their AGN and SF contributions instead of radio loudness; our new definition unifies previously divergent observational results on the role of $M_\mathrm{BH}$ in quasar radio emissions. We further demonstrate that this radio enhancement in quasars with the 20 per cent most massive SMBHs affects only the $\sim 5~{{\rm per\ cent}}$ most radio bright quasars at a given redshift and bolometric luminosity. We discuss possible physical origins of this radio excess in the most massive and radio-bright quasar population, which remains an interest for future study.

The observed phase space of mass-loss history from massive stars based on radio observations of a large supernova sample

(2025)

Authors:

Itai Sfaradi, Assaf Horesh, Rob Fender, Lauren Rhodes, Joe Bright, David Williams-Baldwin, Dave A Green

Detection of very-high-energy gamma-ray emission from Eta Carinae during its 2020 periastron passage

(2025)

Authors:

HESS Collaboration, F Aharonian, F Ait Benkhali, J Aschersleben, H Ashkar, V Barbosa Martins, R Batzofin, Y Becherini, D Berge, K Bernlöhr, M Böttcher, C Boisson, J Bolmont, M de Bony de Lavergne, F Bradascio, R Brose, A Brown, F Brun, B Bruno, C Burger-Scheidlin, S Casanova, J Celic, M Cerruti, T Chand, S Chandra, A Chen, J Chibueze, O Chibueze, T Collins, G Cotter, J Damascene Mbarubucyeye, J de Assis Scarpin, J Devin, A Djannati-Ataï, J Djuvsland, A Dmytriiev, K Egberts, S Einecke, J-P Ernenwein, C Escañuela Nieves, K Feijen, M Filipovic, G Fontaine, S Funk, S Gabici, JF Glicenstein, G Grolleron, M-H Grondin, L Haerer, B Heß, JA Hinton, W Hofmann, TL Holch, M Holler, D Horns, Zhiqiu Huang, M Jamrozy, F Jankowsky, A Jardin-Blicq, I Jung-Richardt, K Katarzyński, R Khatoon, B Khélifi, W Kluźniak, Nu Komin, K Kosack, D Kostunin, RG Lang, S Le Stum, A Lemière, M Lemoine-Goumard, J-P Lenain, A Luashvili, J Mackey, D Malyshev, V Marandon, A Marcowith, G Martí-Devesa, R Marx, A Mehta, A Mitchell, R Moderski, MO Moghadam, L Mohrmann, E Moulin, M de Naurois, J Niemiec, S Ohm, L Olivera-Nieto, E de Ona Wilhelmi, M Ostrowski, S Panny, M Panter, RD Parsons, U Pensec, G Pühlhofer, A Quirrenbach, S Ravikularaman, M Regeard, A Reimer, O Reimer, Q Remy, H Ren, B Reville, F Rieger, G Rowell, B Rudak, E Ruiz-Velasco, K Sabri, V Sahakian, H Salzmann, A Santangelo, M Sasaki, J Schäfer, F Schüssler, HM Schutte, JNS Shapopi, S Spencer, Ł Stawarz, R Steenkamp, S Steinmassl, C Steppa, K Streil, T Tanaka, R Terrier, M Tluczykont, M Tsirou, N Tsuji, C van Eldik, M Vecchi, C Venter, T Wach, SJ Wagner, F Werner, R White, A Wierzcholska, M Zacharias, AA Zdziarski, A Zech, N Żywucka

Dependence of Metal Enrichment of Nuclear Star Clusters on Galaxy Stellar Mass

The Astrophysical Journal American Astronomical Society 979:1 (2025) 85

Authors:

Wenhe Lyu, Hong-Xin Zhang, Sanjaya Paudel, Tie Li, Yimeng Tang, Guangwen Chen, Xu Kong, Eric W Peng

Abstract:

Nuclear star clusters (NSCs) are commonly found in the centers of galaxies, but their dominant formation mechanisms remain elusive. We perform a consistent analysis of stellar populations of 97 nearby NSCs, based on spectroscopic data from the Very Large Telescope. The sample covers a galaxy stellar mass range of 107–1011 M⊙ and is more than 3 times larger than any previous study. We identify three galaxy stellar mass regimes with distinct NSC properties. In the low-mass regime of logMhost ≲ 8.5 (Mhost is in units of M⊙), nearly all NSCs have metallicities lower than their circum-NSC host but similar to those of typical red globular clusters (GCs), supporting the GC inspiral–merger scenario of NSC formation. In the high-mass regime of logMhost ≳ 9.5, nearly all NSCs have higher metallicities than their circum-NSC host and red GCs, suggesting significant contributions from in situ star formation. In the intermediate-mass regime, a comparable fraction of NSCs have higher or lower metallicities than their circum-NSC host and red GCs, with no clear dependence on NSC mass, suggesting intermittent in situ star formation. The majority of NSCs with higher metallicities than their host exhibit a negative age–metallicity correlation, providing clear evidence of long-term chemical enrichment. The average metallicity difference between NSC and host peaks broadly around logMhost∼9.8 and declines toward both higher and lower galaxy masses. We find that the efficiency of dynamical-friction-driven inspiral of GCs observed in present-day galaxies can explain the NSC mass at logMhost≲9.5 but falls short of observed ones at higher galaxy mass, reinforcing our conclusions based on stellar population analysis.

Discovery of 26 new Galactic radio transients by MeerTRAP

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) (2025) staf098

Authors:

JD Turner, BW Stappers, J Tian, MC Bezuidenhout, M Caleb, LN Driessen, F Jankowski, I Pastor-Marazuela, KM Rajwade, M Surnis, M Kramer, ED Barr, M Berezina