Rubin-LSST

The effect of minor and major mergers on the evolution of low-excitation radio galaxies

Astrophysical Journal American Astronomical Society 878:2 (2019) 88

Authors:

YA Gordon, KA Pimbblet, S Kaviraj, Owers, CP O'Dea, Mike Walmsley, Baum, JP Crossett, A Fraser-Mckelvie, Christopher Lintott, JCS Pierce

Abstract:

We use deep, μ r ≲ 28 mag arcsec−2, r-band imaging from the Dark Energy Camera Legacy Survey to search for past, or ongoing, merger activity in a sample of 282 low-excitation radio galaxies (LERGs) at z < 0.07. Our principal aim is to assess the the role of mergers in the evolution of LERGs. Exploiting the imaging depth, we classify tidal remnants around galaxies as both minor and major morphological disturbances for our LERG sample and 1622 control galaxies matched in redshift, stellar mass, and environment. In groups and in the field, the LERG minor merger fraction is consistent with the control population. In galaxy clusters, 8.8 ± 2.9% of LERGs show evidence of recent minor mergers in contrast to 23.0 ± 2.0% of controls. This ~4σ deficit of minor mergers in cluster LERGs suggests these events may inhibit this type of nuclear activity for galaxies within the cluster environment. We observe a >4σ excess of major mergers in the LERGs with M * ≲ 1011 M⊙, with 10 ± 1.5% of these active galactic nuclei involved in such large-scale interactions compared to 3.2 ± 0.4% of control galaxies. This excess of major mergers in LERGs decreases with increasing stellar mass, vanishing by M * > 1011.3 M⊙. These observations show that minor mergers do not fuel LERGs, and are consistent with typical LERGs being powered by accretion of matter from their halo. Where LERGs are associated with major mergers, these objects may evolve into more efficiently accreting active galactic nuclei as the merger progresses and more gas falls on to the central engine.

A rapidly-changing jet orientation in the stellar-mass black hole V404 Cygni

(2019)

Authors:

James CA Miller-Jones, Alexandra J Tetarenko, Gregory R Sivakoff, Matthew J Middleton, Diego Altamirano, Gemma E Anderson, Tomaso M Belloni, Rob P Fender, Peter G Jonker, Elmar G Körding, Hans A Krimm, Dipankar Maitra, Sera Markoff, Simone Migliari, Kunal P Mooley, Michael P Rupen, David M Russell, Thomas D Russell, Craig L Sarazin, Roberto Soria, Valeriu Tudose

Hard-state accretion disk winds from black holes: the revealing case of MAXI J1820+070

(2019)

Authors:

T Muñoz-Darias, F Jiménez-Ibarra, G Panizo-Espinar, J Casares, D Mata Sánchez, G Ponti, RP Fender, DAH Buckley, P Garnavich, MAP Torres, M Armas Padilla, PA Charles, JM Corral-Santana, JJE Kajava, EJ Kotze, C Littlefield, J Sánchez-Sierras, D Steeghs, J Thomas

ALMA observations of A0620-00: fresh clues on the nature of quiescent black hole X-ray binary jets

(2019)

Authors:

Elena Gallo, Richard Teague, Richard M Plotkin, James CA Miller-Jones, David M Russell, Tolga Dinçer, Charles Bailyn, Thomas J Maccarone, Sera Markoff, Rob P Fender

Radio source extraction with ProFound

Monthly Notices of the Royal Astronomical Society Oxford University Press 487:3 (2019) 3971-3989

Authors:

CL Hale, ASG Robotham, LJM Davies, Matthew Jarvis, SP Driver, I Heywood

Abstract:

In the current era of radio astronomy, continuum surveys observe a multitude of objects with complex morphologies and sizes, and are not limited to observing point sources. Typical radio source extraction software generates catalogues by using Gaussian components to form a model of the emission. This may not be well suited to complicated jet structures and extended emission, particularly in the era of interferometers with a high density of short baselines, which are sensitive to extended emission. In this paper, we investigate how the optically motivated source detection package ProFound (Robotham et al. 2018) may be used to model radio emission of both complicated and point-like radio sources. We use a combination of observations and simulations to investigate how ProFound compares to other source extractor packages used for radio surveys. We find that ProFound can accurately recover both the flux densities of simulated Gaussian sources as well as extended radio galaxies. ProFound can create models that trace the complicated nature of these extended galaxies, which we show is not necessarily the case with other source extraction software. Our work suggests that our knowledge of the emission from extended radio objects may be both over or under-estimated using traditional software. We suggest that ProFound offers a useful alternative to the fitting of Gaussian components for generating catalogues from current and future radio surveys. Furthermore, ProFound's multiwavelength capabilities will be useful in investigating radio sources in combination with multiwavelength data.