Hintze Centre for Astrophysical Surveys

Investigating the properties of stripped-envelope supernovae, what are the implications for their progenitors?

(2018)

Authors:

SJ Prentice, C Ashall, PA James, L Short, PA Mazzali, D Bersier, PA Crowther, C Barbarino, T-W Chen, CM Copperwheat, MJ Darnley, L Denneau, N Elias-Rosa, M Fraser, L Galbany, A Gal-Yam, J Harmanen, DA Howell, G Hosseinzadeh, C Inserra, E Kankare, E Karamehmetoglu, GP Lamb, M Limongi, K Maguire, C McCully, F Olivares E., AS Piascik, G Pignata, DE Reichart, A Rest T Reynolds, Ó Rodríguez, JLO Saario, S Schulze, SJ Smartt, KW Smith, J Sollerman, B Stalder, M Sullivan, F Taddia, S Valenti, SD Vergani, SC Williams, DR Young

A connection between accretion states and the formation of ultrarelativistic outflows in a neutron star X-ray binary

Monthly Notices of the Royal Astronomical Society Oxford University Press 483:3 (2018) 3686-3699

Authors:

Sara Motta, RP Fender

Abstract:

The nearby accreting neutron star binary Sco X-1 is the closest example of ongoing relativistic jet production at high Eddington ratios. Previous radio studies have revealed that alongside mildly relativistic, radio-emitting ejecta, there is at times a much faster transfer of energy from the region of the accretion flow along the jet. The nature of this ultrarelativistic flow remains unclear and while there is some evidence for a similar phenomenon in other systems that might contain neutron stars, it has never been observed in a confirmed black hole system. We have compared these previous radio observations with a new analysis of simultaneous X-ray observations that were performed with the RXTE mission. We find that the ejection of the ultrarelativistic flow seems to be associated with the simultaneous appearance of two particular types of quasi-periodic oscillations in the X-ray power spectrum. In contrast, the mildly relativistic, radio-emitting outflows may be associated with flat-topped broad-band noise in the X-ray power spectrum. This is the first time a link, albeit tentative, has been found between these mysterious unseen flows and the accretion flow from which they are launched.

Observations of SN 2017ein Reveal Shock Breakout Emission and A Massive Progenitor Star for a Type Ic Supernova

(2018)

Authors:

Danfeng Xiang, Xiaofeng Wang, Jun Mo, Lingjun Wang, Stephen Smartt, Morgan Fraser, Shuhrat A Ehgamberdiev, Davron Mirzaqulov, Jujia Zhang, Tianmeng Zhang, Jozsef Vinko, J Craig Wheeler, Griffin Hosseinzadeh, D Andrew Howell, Curtis McCully, James M DerKacy, E Baron, Peter Brown, Xianfei Zhang, Shaolan Bi, Hao Song, Kaicheng Zhang, A Rest, Ken'ichi Nomoto, Alexey Tolstov, Sergei Blinnikov

Don't Blink: Constraining the Circumstellar Environment of the Interacting Type Ia Supernova 2015cp

(2018)

Authors:

CE Harris, PE Nugent, A Horesh, JS Bright, RP Fender, ML Graham, K Maguire, M Smith, N Butler, S Valenti, AV Filippenko, O Fox, A Goobar, PL Kelly, KJ Shen

The effects of galaxy interactions on molecular gas properties

Astrophysical Journal American Astronomical Society 868:2 (2018) 132

Authors:

H-A Pan, L Lin, B-C Hsieh, Martin Bureau

Abstract:

Galaxy interactions are often accompanied by an enhanced star formation rate (SFR). Since molecular gas is essential for star formation, it is vital to establish whether and by how much galaxy interactions affect the molecular gas properties. We investigate the effect of interactions on global molecular gas properties by studying a sample of 58 galaxies in pairs and 154 control galaxies. Molecular gas properties are determined from observations with the JCMT, PMO, and CSO telescopes and supplemented with data from the xCOLD GASS and JINGLE surveys at 12CO(1–0) and 12CO(2–1). The SFR, gas mass (${M}_{{{\rm{H}}}_{2}}$), and gas fraction (f gas) are all enhanced in galaxies in pairs by ~2.5 times compared to the controls matched in redshift, mass, and effective radius, while the enhancement of star formation efficiency (SFE ≡SFR/${M}_{{{\rm{H}}}_{2}}$) is less than a factor of 2. We also find that the enhancements in SFR, ${M}_{{{\rm{H}}}_{2}}$ and f gas, increase with decreasing pair separation and are larger in systems with smaller stellar mass ratio. Conversely, the SFE is only enhanced in close pairs (separation <20 kpc) and equal-mass systems; therefore, most galaxies in pairs lie in the same parameter space on the SFR–${M}_{{{\rm{H}}}_{2}}$ plane as controls. This is the first time that the dependence of molecular gas properties on merger configurations is probed statistically with a relatively large sample and a carefully selected control sample for individual galaxies. We conclude that galaxy interactions do modify the molecular gas properties, although the strength of the effect is dependent on merger configuration.