VAST: An ASKAP Survey for Variables and Slow Transients

Murphy, Tara; Chatterjee, Shami; Kaplan, David L.; Banyer, J.; Bell, M. E.; Bignall, H. E.; Bower, Geoffrey C.; Cameron, R. A.; Coward, D. M.; Cordes, J. M.; Croft, Steve; Curran, James; Djorgovski, S. G.; Farrell, Sean; Frail, D. A.; Gaensler, B. M.; Galloway, D. K.; Gendre, B.; Green, Anne; Hancock, P. J.; Johnston, S.; Kamble, A.; Law, Casey J.; Lazio, T. Joseph W.; Lo, Kitty; Macquart, Jean–Pierre; Rea, N.; Rebbapragada, Umaa; Reynolds, C.; Ryder, S. D.; Schmidt, B.; Soria, Roberto; Stairs, I. H.; Tingay, S. J.; Torkelsson, Ulf; Wagstaff, Kiri L.; Walker, Mark A.; Wayth, R. B.; Williams, Peter K. G.

doi:10.1017/pasa.2012.006

Cited by 112 publications

(62 citation statements)

References 231 publications

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“…We next calculated the coherent burst duty cycle and expected transient density for the frequency bands of three ongoing or upcoming transient surveys ( Figure 6): VAST (1.13-1.43 GHz;Murphy et al 2013), ThunderKAT L-band (0.9-1.67 GHz; but we used 1-1.67 GHz, the part of the band that overlaps with our frequency coverage), and VLASS (2-4 GHz). We generated these predictions following the same procedure described in the previous section, but using a shorter integration time of 150 sec, enabled by the better sen-sitivity of these bands compared to the 340-480 MHz band considered in the previous section.…”

Section: Application To Current Transient Surveysmentioning

confidence: 99%

Ultra-wideband Detection of 22 Coherent Radio Bursts on M Dwarfs

Villadsen

Hallinan

2019

ApJ

106

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Coherent radio bursts detected from M dwarfs have some analogy with solar radio bursts, but reach orders of magnitude higher luminosities. These events trace particle acceleration, powered by magnetic reconnection, shock fronts (such as formed by coronal mass ejections, CMEs), and magnetospheric currents, in some cases offering the only window into these processes in stellar atmospheres. We conducted a 58-hour, ultra-wideband survey for coherent radio bursts on 5 active M dwarfs. We used the Karl G. Jansky Very Large Array (VLA) to observe simultaneously in three frequency bands covering a subset of 224-482 MHz and 1-6 GHz, achieving the widest fractional bandwidth to date for any observations of stellar radio bursts. We detected 22 bursts across 13 epochs, providing the first large sample of wideband dynamic spectra of stellar coherent radio bursts. The observed bursts have diverse morphology, with durations ranging from seconds to hours, but all share strong (40-100%) circular polarization. No events resemble solar Type II bursts (often associated with CMEs), but we cannot rule out the occurrence of radio-quiet stellar CMEs. The hours-long bursts are all polarized in the sense of the x-mode of the star's large-scale magnetic field, suggesting they are cyclotron maser emission from electrons accelerated in the large-scale field, analogous to auroral processes on ultracool dwarfs. The duty cycle of luminous coherent bursts peaks at 25% at 1-1.4 GHz, declining at lower and higher frequencies, indicating source regions in the low corona. At these frequencies, active M dwarfs should be the most common galactic transient source.

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Section: Application To Current Transient Surveysmentioning

confidence: 99%

Ultra-wideband Detection of 22 Coherent Radio Bursts on M Dwarfs

Villadsen

Hallinan

2019

ApJ

106

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“…The combination of the sophisticated and powerful LOFAR computing platform, the low observing frequency and the dipole-like receiving elements means that these surveys will revolutionize our understanding of the transient radio sky. The other SKA precursor telescopes such as ASKAP and MeerKAT also have planned transient programmes: VAST [32], CRAFT, TRAPUM and ThunderKAT [13], and these will all help pave the way for transient searches with the SKA in both phases. In addition to these new observing projects, there are exciting new developments in detection methods such as multi-moment analysis [33], the Chirpolator and Chimageator [34], millisecond imaging [35] and the use of interferometric closure quantities [36].…”

Section: The Present and Near Futurementioning

confidence: 99%

The square kilometre array and the transient universe

Stappers

2013

Phil. Trans. R. Soc. A.

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The square kilometre array (SKA) is a next generation radio telescope that will be built in southern Africa and Australasia. It will be built in two phases and will use a range of detectors, from aperture arrays to dishes, to span the frequency range from a few tens of megahertz to a few gigahertz. The combination of great sensitivity, wide field of view and unprecedented computing power mean that the SKA will be an excellent instrument for studying the transient radio universe. Transient radio emission is generated in extremes of: gravitational and magnetic fields, velocity, temperature, pressure and density. While we know about plenty of source classes for this type of short duration radio emission, there is still a large range of transient parameter space that has not yet been sampled owing to the limitations of current generation radio telescopes.

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“…Blind searches for radio transients using interferometers present many challenges, particularly modest field of view (FoV) and limited observing cadence (e.g. Murphy et al 2013;Mooley et al 2016Mooley et al , 2018. With current wide FoV ( 1 square degree) instruments such as MeerKAT (Camilo et al 2018), the Australian Square Kilometer Array Pathfinder (ASKAP; Johnston et al 2008;Schinckel et al 2012), APERTIF (Maan & van Leeuwen 2017), the LOw Frequency Array (LOFAR; van Haarlem et al 2013), and the Murchison Wide Field Array (MWA; Tingay et al 2012), surveying large areas of sky with various cadences and improved sensitivity is now possible.…”

Section: Introductionmentioning

confidence: 99%

MKT J170456.2–482100: the first transient discovered by MeerKAT

Driessen

McDonald

Buckley

et al. 2019

Monthly Notices of the Royal Astronomical Society

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We report the discovery of the first transient with MeerKAT, MKT J170456.2−482100, discovered in ThunderKAT images of the low mass X-ray binary GX339−4. MKT J170456.2−482100 is variable in the radio, reaching a maximum flux density of 0.71 ± 0.11 mJy on 2019 Oct 12, and is undetected in 15 out of 48 ThunderKAT epochs. MKT J170456.2−482100 is coincident with the chromospherically active Ktype sub-giant TYC 8332-2529-1, and ∼ 18 years of archival optical photometry of the star shows that it varies with a period of 21.25 ± 0.04 days. The shape and phase of the optical light curve changes over time, and we detect both X-ray and UV emission at the position of MKT J170456.2−482100, which may indicate that TYC 8332-2529-1 has large star spots. Spectroscopic analysis shows that TYC 8332-2529-1 is in a binary, and has a line-of-sight radial velocity amplitude of 43 km s −1 . We also observe a spectral feature in anti-phase with the K-type sub-giant, with a line-of-sight radial velocity amplitude of ∼ 12 ± 10 km s −1 , whose origins cannot currently be explained. Further observations and investigation are required to determine the nature of the MKT J170456.2−482100 system.

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VAST: An ASKAP Survey for Variables and Slow Transients

Cited by 112 publications

References 231 publications

Ultra-wideband Detection of 22 Coherent Radio Bursts on M Dwarfs

Ultra-wideband Detection of 22 Coherent Radio Bursts on M Dwarfs

The square kilometre array and the transient universe

MKT J170456.2–482100: the first transient discovered by MeerKAT

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