MeerKAT

LOFAR 150-MHz observations of the Boötes field: catalogue and source counts

Monthly Notices of the Royal Astronomical Society Oxford University Press 430:3 (2016) 2385-2412

Authors:

WL Williams, RJ van Weeren, HJA Röttgering, P Best, TJ Dijkema, FD Gasperin, MJ Hardcastle, G Heald, I Prandoni, J Sabater, TW Shimwell, C Tasse, IMV Bemmel, M Brüggen, G Brunetti, JE Conway, T Enßlin, D Engels, H Falcke, C Ferrari, M Haverkorn, N Jackson, Matthew Jarvis, AD Kapinska, EK Mahony, GK Miley, LK Morabito, R Morganti, E Orrú, E Retana-Montenegro, SS Sridhar, MC Toribio, GJ White, MW Wise, JTL Zwart

Abstract:

We present the first wide area (19 deg$^2$), deep ($\approx120-150$ {\mu}Jy beam$^{-1}$), high resolution ($5.6 \times 7.4$ arcsec) LOFAR High Band Antenna image of the Bo\"otes field made at 130-169 MHz. This image is at least an order of magnitude deeper and 3-5 times higher in angular resolution than previously achieved for this field at low frequencies. The observations and data reduction, which includes full direction-dependent calibration, are described here. We present a radio source catalogue containing 6276 sources detected over an area of $19$\,deg$^2$, with a peak flux density threshold of $5\sigma$. As the first thorough test of the facet calibration strategy, introduced by van Weeren et al., we investigate the flux and positional accuracy of the catalogue. We present differential source counts that reach an order of magnitude deeper in flux density than previously achieved at these low frequencies, and show flattening at 150 MHz flux densities below 10 mJy associated with the rise of the low flux density star-forming galaxies and radio-quiet AGN.

MeerTime - the MeerKAT Key science program on pulsar timing

Proceedings of Science (2016)

Authors:

M Bailes, E Barr, NDR Bhat, J Brink, S Buchner, M Burgay, F Camilo, DJ Champion, J Hessels, GH Jansseng, A Jameson, S Johnston, A Karastergiou, R Karuppusamy, V Kaspi, MJ Keith, M Kramer, MA McLaughlin, K Moodley, S Oslowski, A Possenti, SM Ransom, FA Rasio, J Sievers, M Serylak, BW Stappers, IH Stairs, G Theureau, W van Straten, P Weltevrede, N Wex

Abstract:

© Copyright owned by the author(s). The MeerKAT telescope represents an outstanding opportunity for radio pulsar timing science with its unique combination of a large collecting area and aperture efficiency (effective area ∼7500 m2), system temperature (T < 20K), high slew speeds (1-2 deg/s), large bandwidths (770 MHz at 20cm wavelengths), southern hemisphere location (latitude ∼ −30◦) and ability to form up to four sub-arrays. The MeerTime project is a five-year program on the MeerKAT array by an international consortium that will regularly time over 1000 radio pulsars to perform tests of relativistic gravity, search for the gravitational wave signature induced by supermassive black hole binaries in the timing residuals of millisecond pulsars, explore the interiors of neutron stars through a pulsar glitch monitoring programme, explore the origin and evolution of binary pulsars, monitor the swarms of pulsars that inhabit globular clusters and monitor radio magnetars. MeerTime will complement the TRAPUM project and time pulsars TRAPUM discovers in surveys of the galactic plane, globular clusters and the galactic centre. In addition to these primary programmes, over 1000 pulsars will have their arrival times monitored and the data made immediately public. The MeerTime pulsar backend comprises two server-class machines each of which possess four Graphics Processing Units. Up to four pulsars can be coherently dedispersed simultaneously up to dispersion measures of over 1000 pc cm−3. All data will be provided in psrfits format. The MeerTime backend will be capable of producing coherently dedispersed filterbank data for timing multiple pulsars in the cores of globular clusters that is useful for pulsar searches of tied array beams. The first real-time pulsar profiles have been obtained as part of the MeerKAT commissioning process, and useful scientific data will start to come online through 2017. All MeerTime data will ultimately be made available for public use, and any published results will include the arrival times and profiles used in the results.

MeerTime - the MeerKAT Key science program on pulsar timing

Proceedings of Science (2016)

Authors:

M Bailes, E Barr, NDR Bhat, J Brink, S Buchner, M Burgay, F Camilo, DJ Champion, J Hessels, GH Jansseng, A Jameson, S Johnston, A Karastergiou, R Karuppusamy, V Kaspi, MJ Keith, M Kramer, MA McLaughlin, K Moodley, S Oslowski, A Possenti, SM Ransom, FA Rasio, J Sievers, M Serylak, BW Stappers, IH Stairs, G Theureau, W van Straten, P Weltevrede, N Wex

Abstract:

The MeerKAT telescope represents an outstanding opportunity for radio pulsar timing science with its unique combination of a large collecting area and aperture efficiency (effective area ∼7500 m2), system temperature (T < 20K), high slew speeds (1-2 deg/s), large bandwidths (770 MHz at 20cm wavelengths), southern hemisphere location (latitude ∼ −30◦) and ability to form up to four sub-arrays. The MeerTime project is a five-year program on the MeerKAT array by an international consortium that will regularly time over 1000 radio pulsars to perform tests of relativistic gravity, search for the gravitational wave signature induced by supermassive black hole binaries in the timing residuals of millisecond pulsars, explore the interiors of neutron stars through a pulsar glitch monitoring programme, explore the origin and evolution of binary pulsars, monitor the swarms of pulsars that inhabit globular clusters and monitor radio magnetars. MeerTime will complement the TRAPUM project and time pulsars TRAPUM discovers in surveys of the galactic plane, globular clusters and the galactic centre. In addition to these primary programmes, over 1000 pulsars will have their arrival times monitored and the data made immediately public. The MeerTime pulsar backend comprises two server-class machines each of which possess four Graphics Processing Units. Up to four pulsars can be coherently dedispersed simultaneously up to dispersion measures of over 1000 pc cm−3. All data will be provided in psrfits format. The MeerTime backend will be capable of producing coherently dedispersed filterbank data for timing multiple pulsars in the cores of globular clusters that is useful for pulsar searches of tied array beams. The first real-time pulsar profiles have been obtained as part of the MeerKAT commissioning process, and useful scientific data will start to come online through 2017. All MeerTime data will ultimately be made available for public use, and any published results will include the arrival times and profiles used in the results.

Optimising commensality of radio continuum and spectral line observations in the era of the SKA

Monthly Notices of the Royal Astronomical Society Oxford University Press (2016) stw1164-stw1164

Authors:

Natasha Maddox, Matthew Jarvis, TA Oosterloo

Abstract:

The substantial decrease in star formation density from z=1 to the present day is curious given the relatively constant neutral gas density over the same epoch. Future radio astronomy facilities, including the SKA and pathfinder telescopes, will provide pioneering measures of both the gas content of galaxies and star formation activity over cosmological timescales. Here we investigate the commensalities between neutral atomic gas (HI) and radio continuum observations, as well as the complementarity of the data products. We start with the proposed HI and continuum surveys to be undertaken with the SKA precursor telescope MeerKAT, and building on this, explore optimal combinations of survey area coverage and depth of proposed HI and continuum surveys to be undertaken with the SKA1-MID instrument. Intelligent adjustment of these observational parameters results in a tiered strategy that minimises observation time while maximising the value of the dataset, both for HI and continuum science goals. We also find great complementarity between the HI and continuum datasets, with the spectral line HI data providing redshift measurements for gas-rich, star-forming galaxies with stellar masses Mstellar~10^9 Msun to z~0.3, a factor of three lower in stellar mass than would be feasible to reach with large optical spectroscopic campaigns.

Supernova rates from the SUDARE VST-Omegacam search II. Rates in a galaxy sample

Astronomy and Astrophysics EDP Sciences 598:February 2017 (2016) A50

Authors:

MT Botticella, E Cappellaro, L Greggio, G Pignata, MD Valle, A Grado, L Limatola, A Baruffolo, S Benetti, F Bufano, M Capaccioli, E Cascone, G Covone, DD Cicco, S Falocco, Boris Haeussler, V Harutyunyan, Matthew Jarvis, L Marchetti, NR Napolitano, M Paolillo, A Pastorello, M Radovich, P Schipani, L Tomasella, M Turatto, M Vaccari

Abstract:

This is the second paper of a series in which we present measurements of the Supernova (SN) rates from the SUDARE survey. In this paper, we study the trend of the SN rates with the intrinsic colours, the star formation activity and the mass of the parent galaxies. We have considered a sample of about 130000 galaxies and a SN sample of about 50 events. We found that the SN Ia rate per unit mass is higher by a factor of six in the star-forming galaxies with respect to the passive galaxies. The SN Ia rate per unit mass is also higher in the less massive galaxies that are also younger. These results suggest a distribution of the delay times (DTD) less populated at long delay times than at short delays. The CC SN rate per unit mass is proportional to both the sSFR and the galaxy mass. The trends of the Type Ia and CC SN rates as a function of the sSFR and the galaxy mass that we observed from SUDARE data are in agreement with literature results at different redshifts. The expected number of SNe Ia is in agreement with the observed one for all four DTD models considered both in passive and star-forming galaxies so we can not discriminate between different progenitor scenarios. The expected number of CC SNe is higher than the observed one, suggesting a higher limit for the minimum progenitor mass. We also compare the expected and observed trends of the SN Ia rate with the intrinsic U - J colour of the parent galaxy, assumed as a tracer of the age distribution. While the slope of the relation between the SN Ia rate and the U - J color in star-forming galaxies can be reproduced well by all four DTD models considered, only the steepest of them is able to account for the rates and colour in star-forming and passive galaxies with the same value of the SN Ia production efficiency.