The Square Kilometre Array (SKA)

A novel Bayesian approach for decomposing the radio emission of quasars: I. Modelling the radio excess in red quasars

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 529:4 (2024) 3939-3957

Authors:

B-H Yue, PN Best, KJ Duncan, G Calistro-Rivera, LK Morabito, JW Petley, I Prandoni, HJA Röttgering, DJB Smith

Abstract:

ABSTRACT Studies show that both radio jets from the active galactic nuclei (AGNs) and the star formation (SF) activity in quasar host galaxies contribute to the quasar radio emission; yet their relative contributions across the population remain unclear. Here, we present an improved parametric model that allows us to statistically separate the SF and AGN components in observed quasar radio flux density distributions, and investigate how their relative contributions evolve with AGN bolometric luminosity ($L_\mathrm{bol}$) and redshift (z) using a fully Bayesian method. Based on the newest data from LOw-Frequency ARray Two-metre Sky Survey data release 2, our model gives robust fitting results out to $z\sim 4$, showing a quasar host galaxy SF rate (SFR) evolution that increases with bolometric luminosity and with redshift out to $z\sim 4$. This differs from the global cosmic SFR density, perhaps due to the importance of galaxy mergers. The prevalence of radio AGN emissions increases with quasar luminosity, but has little dependence on redshift. Furthermore, our new methodology and large sample size allow us to subdivide our data set to investigate the role of other parameters. Specifically, in this paper, we explore quasar colour and demonstrate that the radio excess in red quasars is due to an enhancement in AGN-related emission, since the host galaxy SF contribution to the total radio emission is independent of quasar colour. We also find evidence that this radio enhancement occurs mostly in quasars with weak or intermediate radio power.

Spectrum and extension of the inverse-Compton emission of the Crab Nebula from a combined Fermi-LAT and H.E.S.S. analysis

(2024)

Authors:

F Aharonian, F Ait Benkhali, J Aschersleben, H Ashkar, M Backes, A Baktash, V Barbosa Martins, R Batzofin, Y Becherini, D Berge, K Bernlöhr, B Bi, M Böttcher, C Boisson, J Bolmont, M de Bony de Lavergne, J Borowska, F Bradascio, M Breuhaus, R Brose, A Brown, F Brun, B Bruno, T Bulik, C Burger-Scheidlin, T Bylund, S Caroff, S Casanova, R Cecil, J Celic, M Cerruti, P Chambery, T Chand, S Chandra, A Chen, J Chibueze, O Chibueze, G Cotter, P Cristofari, J Devin, A Djannati-Ataï, J Djuvsland, A Dmytriiev, S Einecke, J-P Ernenwein, S Fegan, K Feijen, M Filipović, G Fontaine, M Füßling, S Funk, S Gabici, YA Gallant, G Giavitto, D Glawion, JF Glicenstein, J Glombitza, P Goswami, G Grolleron, M-H Grondin, L Haerer, JA Hinton, W Hofmann, TL Holch, M Holler, D Horns, M Jamrozy, F Jankowsky, V Joshi, E Kasai, K Katarzyński, R Khatoon, B Khélifi, W Kluźniak, Nu Komin, K Kosack, D Kostunin, A Kundu, RG Lang, S Le Stum, F Leitl, A Lemière, M Lemoine-Goumard, J-P Lenain, F Leuschner, A Luashvili, J Mackey, D Malyshev, D Malyshev, V Marandon, P Marinos, G Martí-Devesa, R Marx, A Mehta, M Meyer, A Mitchell, R Moderski, L Mohrmann, A Montanari, E Moulin, T Murach, M de Naurois, J Niemiec, P O'Brien, S Ohm, L Olivera-Nieto, E de Ona Wilhelmi, M Ostrowski, S Panny, M Panter, RD Parsons, G Peron, DA Prokhorov, G Pühlhofer, M Punch, A Quirrenbach, M Regeard, P Reichherzer, A Reimer, O Reimer, H Ren, M Renaud, B Reville, F Rieger, G Roellinghoff, B Rudak, V Sahakian, H Salzmann, M Sasaki, F Schüssler, HM Schutte, JNS Shapopi, A Specovius, S Spencer, Ł Stawarz, R Steenkamp, S Steinmassl, C Steppa, K Streil, I Sushch, H Suzuki, T Takahashi, T Tanaka, R Terrier, M Tluczykont, N Tsuji, T Unbehaun, C van Eldik, M Vecchi, J Veh, C Venter, J Vink, T Wach, SJ Wagner, A Wierzcholska, M Zacharias, D Zargaryan, AA Zdziarski, A Zech, S Zouari, N Żywucka, A Harding

MIGHTEE-HI: HI galaxy properties in the large scale structure environment at z ∼ 0.37 from a stacking experiment

Monthly Notices of the Royal Astronomical Society Oxford University Press 529:4 (2024) 4192-4209

Authors:

Francesco Sinigaglia, Giulia Rodighiero, Ed Elson, Alessandro Bianchetti, Mattia Vaccari, Natasha Maddox, Anastasia A Ponomareva, Bradley S Frank, Matt J Jarvis, Barbara Catinella, Luca Cortese, Sambit Roychowdhury, Maarten Baes, Jordan D Collier, Olivier Ilbert, Ali A Khostovan, Sushma Kurapati, Hengxing Pan, Isabella Prandoni, Sambatriniaina HA Rajohnson, Mara Salvato, Srikrishna Sekhar, Gauri Sharma

Abstract:

We present the first measurement of HI mass of star-forming galaxies in different large scale structure environments from a blind survey at z ∼ 0.37. In particular, we carry out a spectral line stacking analysis considering 2875 spectra of colour-selected star-forming galaxies undetected in HI at 0.23 < z < 0.49 in the COSMOS field, extracted from the MIGHTEE-HI Early Science datacubes, acquired with the MeerKAT radio telescope. We stack galaxies belonging to different subsamples depending on three different definitions of large scale structure environment: local galaxy overdensity, position inside the host dark matter halo (central, satellite, or isolated), and cosmic web type (field, filament, or knot). We first stack the full star-forming galaxy sample and find a robust HI detection yielding an average galaxy HI mass of MHI = (8.12 ± 0.75) × 109 M⊙ at ∼11.8σ. Next, we investigate the different subsamples finding a negligible difference in MHI as a function of the galaxy overdensity. We report an HI excess compared to the full sample in satellite galaxies (MHI = (11.31 ± 1.22) × 109, at ∼10.2σ) and in filaments (MHI = (11.62 ± 0.90) × 109. Conversely, we report non-detections for the central and knot galaxies subsamples, which appear to be HI-deficient. We find the same qualitative results also when stacking in units of HI fraction (fHI). We conclude that the HI amount in star-forming galaxies at the studied redshifts correlates with the large scale structure environment.

Multiwavelength Pulsations and Surface Temperature Distribution in the Middle-aged Pulsar B1055–52

The Astrophysical Journal American Astronomical Society 963:2 (2024) 138

Authors:

Armin Vahdat, B Posselt, GG Pavlov, P Weltevrede, A Santangelo, S Johnston

Abstract:

We present a detailed study of the X-ray emission from PSR B1055–52 using XMM-Newton observations from 2019 and 2000. The phase-integrated X-ray emission from this pulsar is poorly described by existing models of neutron star atmospheres. Instead, we confirm that, similar to other middle-aged pulsars, the best-fitting spectral model consists of two blackbody components, with substantially different temperatures and emitting areas, and a nonthermal component characterized by a power law. Our phase-resolved X-ray spectral analysis using this three-component model reveals variations in the thermal emission parameters with the pulsar’s rotational phase. These variations suggest a nonuniform temperature distribution across the neutron star’s surface, including the cold thermal component and probable hot spot(s). Such a temperature distribution can be caused by external and internal heating processes, likely a combination thereof. We observe very high pulse fractions, 60%–80% in the 0.7–1.5 keV range, dominated by the hot blackbody component. This could be related to temperature nonuniformity and potential beaming effects in an atmosphere. We find indication of a second hot spot that appears at lower energies (0.15–0.3 keV) than the first hot spot (0.5–1.5 keV) in the X-ray light curves and is offset by about half a rotation period. This finding aligns with the nearly orthogonal rotator geometry suggested by radio observations of this interpulse pulsar. If the hot spots are associated with polar caps, a possible explanation for their temperature asymmetry could be an offset magnetic dipole and/or an additional toroidal magnetic field component in the neutron star crust.

Physical Properties of Hyperluminous, Dust-obscured Quasars at z ∼ 3: Multiwavelength Spectral Energy Distribution Analysis and Cold Gas Content Revealed by ALMA

The Astrophysical Journal American Astronomical Society 964:1 (2024) 95

Authors:

Weibin Sun, Lulu Fan, Yunkun Han, Kirsten K Knudsen, Guangwen Chen, Hong-Xin Zhang