Hintze Centre for Astrophysical Surveys

Estimating the molecular gas mass of low-redshift galaxies from a combination of mid-infrared luminosity and optical properties

(2019)

Authors:

Yang Gao, Ting Xiao, Cheng Li, Xue-Jian Jiang, Qing-hua Tan, Yu Gao, Christine D Wilson, Martin Bureau, Amelie Saintonge, Jos'e R S'anchez-Gallego, Toby Brown, Christopher J Clark, Ho Seong Hwang, Isabella Lamperti, Lin Lin, Lijie Liu, Dengrong Lu, Hsi-An Pan, Jixian Sun, Thomas G Williams

An ASKAP survey for H I absorption towards dust-obscured quasars

Monthly Notices of the Royal Astronomical Society Oxford University Press 489:4 (2019) 4926-4943

Authors:

M Glowacki, JR Allison, VA Moss, EK Mahony, EM Sadler, JR Callingham, SL Ellison, MT Whiting, JD Bunton, AP Chippendale, Ian Heywood, D McConnell, W Raja, MA Voronkov

Abstract:

Obscuration of quasars by accreted gas and dust, or dusty intervening galaxies, can cause active galactic nuclei (AGN) to be missed in optically selected surveys. Radio observations can overcome this dust bias. In particular, radio surveys searching for H I absorption inform us on how the AGN can impact on the cold neutral gas medium within the host galaxy, or the population of intervening galaxies through the observed line of sight gas kinematics. We present the results of an H I absorption line survey at 0.4 < z < 1 towards 34 obscured quasars with the Australian SKA Pathfinder (ASKAP) commissioning array. We detect three H I absorption lines, with one of these systems previously unknown. Through optical follow-up for two sources, we find that in all detections the H I gas is associated with the AGN, and hence that these AGN are obscured by material within their host galaxies. Most of our sample are compact, and in addition, are either gigahertz peaked spectrum (GPS), or steep spectrum (CSS) sources, both thought to represent young or recently re-triggered radio AGN. The radio spectral energy distribution classifications for our sample agree with galaxy evolution models in which the obscured AGN has only recently become active. Our associated H I detection rate for GPS and compact SS sources matches those of other surveys towards such sources. We also find shallow and asymmetric H I absorption features, which agrees with previous findings that the cold neutral medium in compact radio galaxies is typically kinematically disturbed by the AGN.

SN 2017gmr: An Energetic Type II-P Supernova with Asymmetries

The Astrophysical Journal American Astronomical Society 885:1 (2019)

Authors:

Jennifer E Andrews, DJ Sand, S Valenti, Nathan Smith, Raya Dastidar, DK Sahu, Kuntal Misra, Avinash Singh, D Hiramatsu, PJ Brown, G Hosseinzadeh, S Wyatt, J Vinko, GC Anupama, I Arcavi, Chris Ashall, S Benetti, Marco Berton, KA Bostroem, M Bulla, J Burke, S Chen, L Chomiuk, A Cikota, E Congiu, B Cseh, Scott Davis, N Elias-Rosa, T Faran, Morgan Fraser, L Galbany, C Gall, A Gal-Yam, Anjasha Gangopadhyay, M Gromadzki, J Haislip, DA Howell, EY Hsiao, C Inserra, E Kankare, H Kuncarayakti, V Kouprianov, Brajesh Kumar, Xue Li, Han Lin, K Maguire, P Mazzali, C McCully, P Milne, Jun Mo, N Morrell, M Nicholl, P Ochner, F Olivares, A Pastorello, F Patat, M Phillips, G Pignata, S Prentice, A Reguitti, DE Reichart, Ó Rodríguez, Liming Rui, Pankaj Sanwal, K Sárneczky, M Shahbandeh, Mridweeka Singh, S Smartt, J Strader, MD Stritzinger, R Szakáts, L Tartaglia, Huijuan Wang, Lingzhi Wang, Xiaofeng Wang, JC Wheeler, Danfeng Xiang, O Yaron, DR Young, Junbo Zhang

SN2018kzr: A Rapidly Declining Transient from the Destruction of a White Dwarf

The Astrophysical Journal Letters American Astronomical Society 885:1 (2019) l23

Authors:

Owen R McBrien, Stephen J Smartt, Ting-Wan Chen, Cosimo Inserra, James H Gillanders, Stuart A Sim, Anders Jerkstrand, Armin Rest, Stefano Valenti, Rupak Roy, Mariusz Gromadzki, Stefan Taubenberger, Andreas Flörs, Mark E Huber, Ken C Chambers, Avishay Gal-Yam, David R Young, Matt Nicholl, Erkki Kankare, Ken W Smith, Kate Maguire, Ilya Mandel, Simon Prentice, Ósmar Rodríguez, Jonathan Pineda Garcia, Claudia P Gutiérrez, Lluís Galbany, Cristina Barbarino, Peter SJ Clark, Jesper Sollerman, Shrinivas R Kulkarni, Kishalay De, David AH Buckley, Arne Rau

Synchrotron self-absorption and the minimum energy of optically thick radio flares from stellar mass black holes

Monthly Notices of the Royal Astronomical Society Oxford University Press 489:4 (2019) 4836-4846

Authors:

Rob Fender, Joe Bright

Abstract:

We consider the case of radio flares from black hole X-ray binaries in which the flare spectrum evolves from optically thick to optically thin, under the assumption that this is due to decreasing optical depth to synchrotron self-absorption. We are able to place upper and lower limits on the size of the emitting region associated with a radio flare, and determine the synchrotron source magnetic field and energy as a function of size. The energy has a clear minimum which occurs close to the condition that the magnetic field derived from synchrotron self-absorption equals that calculated from equipartition. This minimum energy estimate is independent of the rise time of the event, and so may be applied to any event for which the peak flux is measured and there is evidence for self-absorption. This is a much more accurate approach to minimum energy estimation than assuming expansion at close to the speed of light. We apply this method to four examples of optically thick radio flares and find that in each case either the filling factor of the synchrotron source is considerably less than unity, or the expansion speed is considerably less than the speed of light. The combination of unity filling factor and expansion speeds close to the speed of light is completely ruled out on energetic grounds for three of the four events we consider. The inferred slowed expansion is consistent with detailed modelling of such events, which has been recently reported in the literature. The minimum power requirements associated with the flares are found to be ∼1036 erg s−1, which are easily accommodated in the context of stellar mass black hole accretion at near-Eddington levels, when these flares typically occur. However, the true jet power could still be orders of magnitude higher.