Hintze Centre for Astrophysical Surveys

VEXAS: VISTA EXtension to Auxiliary Surveys

Astronomy & Astrophysics EDP Sciences 630 (2019) a146

Authors:

C Spiniello, A Agnello

VizieR Online Data Catalog: KiDS-BEXGO catalog (Khramtsov+, 2019)

VizieR Online Data Catalog (2019) J/A+A/632/A56-J/A+A/632/A56

Authors:

V Khramtsov, A Sergeyev, C Spiniello, C Tortora, NR Napolitano, A Agnello, F Getman, JTA de Jong, K Kuijken, M Radovich, H-Y Shan, V Shulga

SN 2016gsd: An unusually luminous and linear type II supernova with high velocities

(2019)

Authors:

TM Reynolds, M Fraser, S Mattila, M Ergon, P Lundqvist, L Dessart, Subo Dong, N Elias-Rosa, L Galbany, CP Gutiérrez, T Kangas, E Kankare, R Kotak, H Kuncarayakti, A Pastorello, O Rodriguez, SJ Smartt, M Stritzinger, L Tomasella, Ping Chen, J Harmanen, G Hozzeinzadeh, D Andrew Howell, C Inserra, M Nicholl, M Nielsen, K Smith, A Somero, R Tronsgaard, DR Young

Late-outburst radio flaring in SS Cyg and evidence for a powerful kinetic output channel in cataclysmic variables

Monthly Notices of the Royal Astronomical Society Oxford University Press 490:1 (2019) L76-L80

Authors:

Rob Fender, Joe Bright, Kunal Mooley, James Miller-Jones

Abstract:

Accreting white dwarfs in binary systems known as cataclysmic variables (CVs) have in recent years been shown to produce radio flares during outbursts, qualitatively similar to those observed from neutron star and black hole X-ray binaries, but their ubiquity and energetic significance for the accretion flow has remained uncertain. We present new radio observations of the CV SS Cyg with Arcminute Microkelvin Imager Large Array, which show for the second time late-ouburst radio flaring, in 2016 April. This flaring occurs during the optical flux decay phase, about 10 d after the well-established early-time radio flaring. We infer that both the early- and late-outburst flares are a common feature of the radio outbursts of SS Cyg, albeit of variable amplitudes, and probably of all dwarf novae. We furthermore present new analysis of the physical conditions in the best-sampled late-outburst flare, from 2016 February, which showed clear optical depth evolution. From this we can infer that the synchrotron-emitting plasma was expanding at about 1 per cent of the speed of light, and at peak had a magnetic field of order 1 G and total energy content ≥10 erg. While this result is independent of the geometry of the synchrotron-emitting region, the most likely origin is in a jet carrying away a significant amount of the available accretion power. 33

ALMACAL – VI. Molecular gas mass density across cosmic time via a blind search for intervening molecular absorbers

Monthly Notices of the Royal Astronomical Society Oxford University Press 490:1 (2019) 1220-1230

Authors:

Anne Klitsch, Celine Peroux, Martin A Zwaan, Ian Smail, Dylan Nelson, Gergo Popping, Chian-Chou Chen, Benedikt Diemer, RJ Ivison, James R Allison, Sebastien Muller, A Mark Swinbank, Aleksandra Hamanowicz, Andrew D Biggs, Rajeshwari Dutta

Abstract:

We are just starting to understand the physical processes driving the dramatic change in cosmic star formation rate between z ∼ 2 and the present day. A quantity directly linked to star formation is the molecular gas density, which should be measured through independent methods to explore variations due to cosmic variance and systematic uncertainties. We use intervening CO absorption lines in the spectra of mm-bright background sources to provide a census of the molecular gas mass density of the Universe. The data used in this work are taken from ALMACAL, a wide and deep survey utilizing the ALMA calibrator archive. While we report multiple Galactic absorption lines and one intrinsic absorber, no extragalactic intervening molecular absorbers are detected. However, due to the large redshift path surveyed (z = 182), we provide constraints on the molecular column density distribution function beyond z ∼ 0. In addition, we probe column densities of N(H2) > 1016 atoms cm−2, 5 orders of magnitude lower than in previous studies. We use the cosmological hydrodynamical simulation IllustrisTNG to show that our upper limits of ρ(H2) 108.3 M Mpc−3 at 0 < z ≤ 1.7 already provide new constraints on current theoretical predictions of the cold molecular phase of the gas. These results are in agreement with recent CO emission-line surveys and are complementary to those studies. The combined constraints indicate that the present decrease of the cosmic star formation rate history is consistent with an increasing depletion of molecular gas in galaxies compared to z ∼ 2.