MeerKAT

MIGHTEE: total intensity radio continuum imaging and the COSMOS / XMM-LSS Early Science fields

ArXiv 2110.00347 (2021)

Authors:

I Heywood, MJ Jarvis, CL Hale, IH Whittam, HL Bester, B Hugo, JS Kenyon, M Prescott, OM Smirnov, C Tasse, JM Afonso, PN Best, JD Collier, RP Deane, BS Frank, MJ Hardcastle, K Knowles, N Maddox, EJ Murphy, I Prandoni, SM Randriamampandry, MG Santos, S Sekhar, F Tabatabaei, AR Taylor, K Thorat

The First Large Absorption Survey in HI (FLASH): I. Science Goals and Survey Design

ArXiv 2110.00469 (2021)

Authors:

JR Allison, EM Sadler, AD Amaral, T An, SJ Curran, J Darling, AC Edge, SL Ellison, KL Emig, BM Gaensler, L Garratt-Smithson, M Glowacki, K Grasha, BS Koribalski, C del P Lagos, P Lah, EK Mahony, SA Mao, R Morganti, VA Moss, M Pettini, KA Pimbblet, C Power, P Salas, L Staveley-Smith, MT Whiting, OI Wong, H Yoon, Z Zheng, MA Zwaan

Abstract:

We describe the scientific goals and survey design of the First Large Absorption Survey in HI (FLASH), a wide field survey for 21-cm line absorption in neutral atomic hydrogen (HI) at intermediate cosmological redshifts. FLASH will be carried out with the Australian Square Kilometre Array Pathfinder (ASKAP) radio telescope and is planned to cover the sky south of $\delta \approx +40$deg at frequencies between 711.5 and 999.5MHz. At redshifts between $z = 0.4$ and $1.0$ (look back times of 4 - 8Gyr), the HI content of the Universe has been poorly explored due to the difficulty of carrying out radio surveys for faint 21-cm line emission and, at ultra-violet wavelengths, space-borne searches for Damped Lyman-$\alpha$ absorption in quasar spectra. The ASKAP wide field of view and large spectral bandwidth, in combination with a radio-quiet site, will enable a search for absorption lines in the radio spectra of bright continuum sources over 80% of the sky. This survey is expected to detect at least several hundred intervening 21-cm absorbers, and will produce an HI-absorption-selected catalogue of galaxies rich in cool, star-forming gas, some of which may be concealed from optical surveys. Likewise, at least several hundred associated 21-cm absorbers are expected to be detected within the host galaxies of radio sources at $0.4 < z < 1.0$, providing valuable kinematical information for models of gas accretion and jet-driven feedback in radio-loud active galactic nuclei. FLASH will also detect OH 18-cm absorbers in diffuse molecular gas, megamaser OH emission, radio recombination lines, and stacked HI emission.

Constraining the properties of dense neutron star cores: the case of the low-mass X-ray binary HETE J1900.1–2455

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 508:1 (2021) 882-894

Authors:

N Degenaar, D Page, J van den Eijnden, MV Beznogov, R Wijnands, M Reynolds

The Hydrogen Intensity and Real-time Analysis eXperiment: 256-Element Array Status and Overview

(2021)

Authors:

Devin Crichton, Moumita Aich, Adam Amara, Kevin Bandura, Bruce A Bassett, Carlos Bengaly, Pascale Berner, Shruti Bhatporia, Martin Bucher, Tzu-Ching Chang, H Cynthia Chiang, Jean-Francois Cliche, Carolyn Crichton, Romeel Dave, Dirk IL de Villiers, Matt A Dobbs, Aaron M Ewall-Wice, Scott Eyono, Christopher Finlay, Sindhu Gaddam, Ken Ganga, Kevin G Gayley, Kit Gerodias, Tim Gibbon, Austin Gumba, Neeraj Gupta, Maile Harris, Heiko Heilgendorf, Matt Hilton, Adam D Hincks, Pascal Hitz, Mona Jalilvand, Roufurd Julie, Zahra Kader, Joseph Kania, Dionysios Karagiannis, Aris Karastergiou, Kabelo Kesebonye, Piyanat Kittiwisit, Jean-Paul Kneib, Kenda Knowles, Emily R Kuhn, Martin Kunz, Roy Maartens, Vincent MacKay, Stuart MacPherson, Christian Monstein, Kavilan Moodley, V Mugundhan, Warren Naidoo, Arun Naidu, Laura B Newburgh, Viraj Nistane, Amanda Di Nitto, Deniz Ölçek, Xinyu Pan, Sourabh Paul, Jeffrey B Peterson, Elizabeth Pieters, Carla Pieterse, Aritha Pillay, Anna R Polish, Liantsoa Randrianjanahary, Alexandre Refregier, Andre Renard, Edwin Retana-Montenegro, Ian H Rout, Cyndie Russeeawon, Alireza Vafaei Sadr, Benjamin RB Saliwanchik, Ajith Sampath, Pranav Sanghavi, Mario G Santos, Onkabetse Sengate, J Richard Shaw, Jonathan L Sievers, Oleg M Smirnov, Kendrick M Smith, Ulrich Armel Mbou Sob, Raghunathan Srianand, Pieter Stronkhorst, Dhaneshwar D Sunder, Simon Tartakovsky, Russ Taylor, Peter Timbie, Emma E Tolley, Junaid Townsend, Will Tyndall, Cornelius Ungerer, Jacques van Dyk, Gary van Vuuren, Keith Vanderlinde, Thierry Viant, Anthony Walters, Jingying Wang, Amanda Weltman, Patrick Woudt, Dallas Wulf, Anatoly Zavyalov, Zheng Zhang

The Thousand-Pulsar-Array programme on MeerKAT: -- VI. Pulse widths of a large and diverse sample of radio pulsars

(2021)

Authors:

B Posselt, A Karastergiou, S Johnston, A Parthasarathy, Mj Keith, Ls Oswald, X Song, P Weltevrede, Ed Barr, S Buchner, M Geyer, M Kramer, Dj Reardon, M Serylak, Rm Shannon, R Spiewak, V Venkatraman Krishnan

Abstract:

We present pulse width measurements for a sample of radio pulsars observed with the MeerKAT telescope as part of the Thousand-Pulsar-Array (TPA) programme in the MeerTime project. For a centre frequency of 1284 MHz, we obtain 762 $W_{10}$ measurements across the total bandwidth of 775 MHz, where $W_{10}$ is the width at the 10% level of the pulse peak. We also measure about 400 $W_{10}$ values in each of the four or eight frequency sub-bands. Assuming, the width is a function of the rotation period P, this relationship can be described with a power law with power law index $\mu=-0.29\pm 0.03$. However, using orthogonal distance regression, we determine a steeper power law with $\mu=-0.63\pm 0.06$. A density plot of the period-width data reveals such a fit to align well with the contours of highest density. Building on a previous population synthesis model, we obtain population-based estimates of the obliquity of the magnetic axis with respect to the rotation axis for our pulsars. Investigating the width changes over frequency, we unambiguously identify a group of pulsars that have width broadening at higher frequencies. The measured width changes show a monotonic behaviour with frequency for the whole TPA pulsar population, whether the pulses are becoming narrower or broader with increasing frequency. We exclude a sensitivity bias, scattering and noticeable differences in the pulse component numbers as explanations for these width changes, and attempt an explanation using a qualitative model of five contributing Gaussian pulse components with flux density spectra that depend on their rotational phase.