MeerKAT

One- and two-point source statistics from the LOFAR Two-metre Sky Survey first data release

Astronomy and Astrophysics EDP Sciences 643 (2020) A100

Authors:

Tm Siewert, C Hale, N Bhardwaj, M Biermann, Dj Bacon, M Jarvis, Hja Rottgering, Dj Schwarz, T Shimwell, Pn Best, Kj Duncan, Mj Hardcastle, J Sabater, C Tasse, Gj White, Wl Williams

Abstract:

Context: The LOFAR Two-metre Sky Survey (LoTSS) will eventually map the complete Northern sky and provide an excellent opportunity to study the distribution and evolution of the large-scale structure of the Universe.

Aims: We test the quality of LoTSS observations through a statistical comparison of the LoTSS first data release (DR1) catalogues to expectations from the established cosmological model of a statistically isotropic and homogeneous Universe.

Methods: We study the point-source completeness and define several quality cuts, in order to determine the count-in-cell statistics and differential source count statistics, and measure the angular two-point correlation function. We use the photometric redshift estimates, which are available for about half of the LoTSS-DR1 radio sources, to compare the clustering throughout the history of the Universe.

Results: For the masked LoTSS-DR1 value-added source catalogue, we find a point-source completeness of 99% above flux densities of 0.8 mJy. The counts-in-cell statistic reveals that the distribution of radio sources cannot be described by a spatial Poisson process. Instead, a good fit is provided by a compound Poisson distribution. The differential source counts are in good agreement with previous findings in deep fields at low radio frequencies and with simulated catalogues from the SKA Design Study and the Tiered Radio Extragalactic Continuum Simulation. Restricting the value added source catalogue to low-noise regions and applying a flux density threshold of 2 mJy provides our most reliable estimate of the angular two-point correlation. Based on the distribution of photometric redshifts and the Planck 2018 best-fit cosmological model, the theoretically predicted angular two-point correlation between 0.1 deg and 6 deg agrees reasonably well with the measured clustering for the sub-sample of radio sources with redshift information.

Conclusions: The deviation from a Poissonian distribution might be a consequence of the multi-component nature of a large number of resolved radio sources and/or of uncertainties on the flux density calibration. The angular two-point correlation function is < 10-2 at angular scales > 1 deg and up to the largest scales probed. At a 2 mJy flux density threshold and at a pivot angle of 1 deg, we find a clustering amplitude of A = (5.1? ±? 0.6) × 10-3 with a slope parameter of γ = 0.74? ±? 0.16. For smaller flux density thresholds, systematic issues are identified, which are most likely related to the flux density calibration of the individual pointings. We conclude that we find agreement with the expectation of large-scale statistical isotropy of the radio sky at the per cent level. The angular two-point correlation agrees well with the expectation of the cosmological standard model.

A Non-equipartition Shock Wave Traveling in a Dense Circumstellar Environment around SN 2020oi

The Astrophysical Journal American Astronomical Society 903:2 (2020) 132

Authors:

Assaf Horesh, Itai Sfaradi, Mattias Ergon, Cristina Barbarino, Jesper Sollerman, Javier Moldon, Dougal Dobie, Steve Schulze, Miguel Pérez-Torres, David RA Williams, Christoffer Fremling, Avishay Gal-Yam, Shrinivas R Kulkarni, Andrew O’Brien, Peter Lundqvist, Tara Murphy, Rob Fender, Shreya Anand, Justin Belicki, Eric C Bellm, Michael W Coughlin, Kishalay De, V Zach Golkhou, Matthew J Graham, Dave A Green, Matt Hankins, Mansi Kasliwal, Thomas Kupfer, Russ R Laher, Frank J Masci, AA Miller, James D Neill, Eran O Ofek, Yvette Perrott, Michael Porter, Daniel J Reiley, Mickael Rigault, Hector Rodriguez, Ben Rusholme, David L Shupe, David Titterington

Evidence for a jet and outflow from Sgr A*: a continuum and spectral line study

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 499:3 (2020) 3909-3931

Authors:

F Yusef-Zadeh, M Royster, M Wardle, W Cotton, D Kunneriath, I Heywood, J Michail

Cosmological 3D H I gas map with HETDEX Ly alpha emitters and eBOSS QSOs at z=2: IGM-Galaxy/QSO connection and a similar to 40 Mpc scale giant H ii bubble candidate

Astrophysical Journal IOP Publishing 903 (2020) 24

Authors:

Shiro Mukae, Masami Ouchi, Gary J Hill, Karl Gebhardt, Erin Mentuch Cooper, Donghui Jeong, Shun Saito, Maximilian Fabricius, Eric Gawiser, Robin Ciardullo, Daniel Farrow, Dustin Davis, Greg Zeimann, Steven L Finkelstein, Caryl Gronwall, Chenxu Liu, Yechi Zhang, Chris Byrohl, Yoshiaki Ono, Donald P Schneider, Matthew Jarvis, Caitlin M Casey, Ken Mawatari

Abstract:

We present cosmological (30−400 Mpc) distributions of neutral hydrogen (H i) in the intergalactic medium (IGM) traced by Lyα emitters (LAEs) and QSOs at z = 2.1–2.5, selected with the data of the ongoing Hobby–Eberly Telescope Dark Energy Experiment (HETDEX) and the eBOSS survey. Motivated by a previous study of Mukae et al., we investigate spatial correlations of LAEs and QSOs with H i tomography maps reconstructed from H i Lyα forest absorption in the spectra of background galaxies and QSOs obtained by the CLAMATO survey and this study, respectively. In the cosmological volume far from QSOs, we find that LAEs reside in regions of strong H i absorption, i.e., H i rich, which is consistent with results of previous galaxy−background QSO pair studies. Moreover, there is an anisotropy in the H i distribution plot of transverse and line-of-sight distances; on average the H i absorption peak is blueshifted by ~200 km s−1 from the LAE Lyα redshift, reproducing the known average velocity offset between the Lyα emission redshift and the galaxy systemic redshift. We have identified a ~40 Mpc scale volume of H i underdensity that is a candidate for a giant H ii bubble, where six QSOs and an LAE overdensity exist at $\left\langle z\right\rangle =2.16$. The coincidence of the QSO and LAE overdensities with the H i underdensity indicates that the ionizing photon radiation of the QSOs has created a highly ionized volume of multiple proximity zones in a matter overdensity. Our results suggest an evolutionary picture where H i gas in an overdensity of galaxies becomes highly photoionized when QSOs emerge in the galaxies.

Probing jet launching in neutron star X-ray binaries: the variable and polarized jet of SAX J1808.4-3658

(2020)

Authors:

MC Baglio, DM Russell, S Crespi, S Covino, A Johar, J Homan, DM Bramich, P Saikia, S Campana, P D'Avanzo, RP Fender, P Goldoni, AJ Goodwin, F Lewis, N Masetti, A Miraval Zanon, SE Motta, T Muñoz-Darias, T Shahbaz