Rubin-LSST

The hybrid radio/X-ray correlation of the black hole transient MAXI J1348-630

Monthly Notices of the Royal Astronomical Society Oxford University Press 505:1 (2021) L58-L63

Authors:

F Carotenuto, S Corbel, E Tremou, Td Russell, A Tzioumis, Rp Fender, Pa Woudt, Se Motta, Jca Miller-Jones, Aj Tetarenko, Gr Sivakoff

Abstract:

Black hole (BH) low mass X-ray binaries in their hard spectral state are found to display two different correlations between the radio emission from the compact jets and the X-ray emission from the inner accretion flow. Here, we present a large data set of quasi-simultaneous radio and X-ray observations of the recently discovered accreting BH MAXI J1348–630 during its 2019/2020 outburst. Our results span almost six orders of magnitude in X-ray luminosity, allowing us to probe the accretion–ejection coupling from the brightest to the faintest phases of the outburst. We find that MAXI J1348–630 belongs to the growing population of outliers at the highest observed luminosities. Interestingly, MAXI J1348–630 deviates from the outlier track at LX ≲ 7 × 1035(D/2.2  kpc)2 erg s−1 and ultimately rejoins the standard track at LX ≃ 1033(D/2.2 kpc)2 erg s−1, displaying a hybrid radio/X-ray correlation, observed only in a handful of sources. However, for MAXI J1348–630 these transitions happen at luminosities much lower than what observed for similar sources (at least an order of magnitude). We discuss the behaviour of MAXI J1348–630 in light of the currently proposed scenarios and highlight the importance of future deep monitorings of hybrid correlation sources, especially close to the transitions and in the low luminosity regime.

The Varying Kinematics of Multiple Ejecta from the Black Hole X-ray Binary MAXI J1820+070

(2021)

Authors:

CM Wood, JCA Miller-Jones, J Homan, JS Bright, SE Motta, RP Fender, S Markoff, TM Belloni, EG Körding, D Maitra, S Migliari, DM Russell, TD Russell, CL Sarazin, R Soria, AJ Tetarenko, V Tudose

The SAMI Galaxy Survey: stellar population and structural trends across the Fundamental Plane

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 504:4 (2021) 5098-5130

Authors:

Francesco D’Eugenio, Matthew Colless, Nicholas Scott, Arjen van der Wel, Roger L Davies, Jesse van de Sande, Sarah M Sweet, Sree Oh, Brent Groves, Rob Sharp, Matt S Owers, Joss Bland-Hawthorn, Scott M Croom, Sarah Brough, Julia J Bryant, Michael Goodwin, Jon S Lawrence, Nuria PF Lorente, Samuel N Richards

The double-peaked Type Ic supernova 2019cad: another SN 2005bf-like object

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 504:4 (2021) 4907-4922

Authors:

CP Gutiérrez, MC Bersten, M Orellana, A Pastorello, K Ertini, G Folatelli, G Pignata, JP Anderson, S Smartt, M Sullivan, M Pursiainen, C Inserra, N Elias-Rosa, M Fraser, E Kankare, S Moran, A Reguitti, TM Reynolds, M Stritzinger, J Burke, C Frohmaier, L Galbany, D Hiramatsu, DA Howell, H Kuncarayakti, S Mattila, T Müller-Bravo, C Pellegrino, M Smith

Probing galaxy bias and intergalactic gas pressure with KiDS Galaxies-tSZ-CMB lensing cross-correlations

Astronomy & Astrophysics EDP Sciences (2021)

Authors:

Z Yan, L van Waerbeke, T Tröster, Ah Wright, D Alonso, M Asgari, M Bilicki, T Erben, S Gu, C Heymans, H Hildebrandt, G Hinshaw, N Koukoufilippas, A Kannawadi, K Kuijken, et al

Abstract:

We constrain the redshift dependence of gas pressure bias $\left\langle b_{y} P_{\mathrm{e}}\right\rangle$ (bias-weighted average electron pressure), which characterises the thermodynamics of intergalactic gas, through a combination of cross-correlations between galaxy positions and the thermal Sunyaev-Zeldovich (tSZ) effect, as well as galaxy positions and the gravitational lensing of the cosmic microwave background (CMB). The galaxy sample is from the fourth data release of the Kilo-Degree Survey (KiDS). The tSZ $y$ map and the CMB lensing map are from the {\textit{Planck}} 2015 and 2018 data releases, respectively. The measurements are performed in five redshift bins with $z\lesssim1$. With these measurements, combining galaxy-tSZ and galaxy-CMB lensing cross-correlations allows us to break the degeneracy between galaxy bias and gas pressure bias, and hence constrain them simultaneously. In all redshift bins, the best-fit values of $\bpe$ are at a level of $\sim 0.3\, \mathrm{meV/cm^3}$ and increase slightly with redshift. The galaxy bias is consistent with unity in all the redshift bins. Our results are not sensitive to the non-linear details of the cross-correlation, which are smoothed out by the {\textit{Planck}} beam. Our measurements are in agreement with previous measurements as well as with theoretical predictions. We also show that our conclusions are not changed when CMB lensing is replaced by galaxy lensing, which shows the consistency of the two lensing signals despite their radically different redshift ranges. This study demonstrates the feasibility of using CMB lensing to calibrate the galaxy distribution such that the galaxy distribution can be used as a mass proxy without relying on the precise knowledge of the matter distribution.