A single fast radio burst localized to a massive galaxy at cosmological distance

Bannister, K. W.; Deller, Adam T.; Phillips, Chris; Macquart, Jean–Pierre; Prochaska, J. Xavier; Tejos, Nicolás; Ryder, S. D.; Sadler, E. M.; Shannon, R. M.; Simha, Sunil; Day, Cherie K.; McQuinn, Matthew; North-Hickey, F. O.; Bhandari, Shivani; Arcus, W.; Bennert, Vardha N.; Burchett, Joseph N.; Bouwhuis, M. C.; Dodson, Richard; Ekers, R. D.; Farah, W.; Flynn, Chris; James, C. W.; Kerr, M.; Lenc, E.; Mahony, E. K.; O’Meara, John M.; Osłowski, S.; Qiu, Hao; Treu, Tommaso; Vivian, U; Bateman, T.; Bock, Douglas C.-J.; Bolton, R.; Brown, Alex; Bunton, John D.; Chippendale, A. P.; Cooray, F. R.; Cornwell, T. J.; Gupta, N.; Hayman, Douglas B.; Kesteven, Michael; Koribalski, B. S.; Macleod, A.; McClure-Griffiths, N. M.; Neuhold, S.; Norris, R. P.; Pilawa, M. A.; Qiao, Rui; Reynolds, John; Roxby, Daniel N.; Shimwell, T. W.; Voronkov, M. A.; Wilson, Dianne J

doi:10.1126/science.aaw5903

Cited by 390 publications

(368 citation statements)

References 87 publications

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“…A few FRBs have been localized, confirming their extragalactic origin, and their host environments have been found fairly different (Chatterjee et al 2017;Michilli et al 2018;. This scenario seems to indicate that FRBs may not be a single class of events, and significant effort is nowadays undertaken gianni.bernardi@inaf.it to localize more bursts (Bailes et al 2017;Bannister et al 2019;Kocz et al 2019).…”

Section: Introductionmentioning

confidence: 75%

The Northern Cross fast radio burst project – I. Overview and pilot observations at 408 MHz

Locatelli

Bernardi

Bianchi

et al. 2020

Monthly Notices of the Royal Astronomical Society

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Fast radio bursts remain one of the most enigmatic astrophysical sources. Observations have significantly progressed over the last few years, thanks to the capabilities of new radio telescopes and the refurbishment of existing ones. Here we describe the upgrade of the Northern Cross radio telescope, operating in the 400-416 MHz frequency band, with the ultimate goal of turning the array into a dedicated instrument to survey the sky for fast radio bursts. We present test observations of the pulsar B0329+54 to characterize the system performance and forecast detectability. Observations with the system currently in place are still limited by modest sky coverage (∼ 9.4 deg 2 ) and biased by smearing of high dispersion measure events within each frequency channels. In its final, upgraded configuration, however, the telescope will be able to carry out unbiased fast radio burst surveys over a ∼ 350 deg 2 instantaneous field of view up to z ∼ 5, with a (nearly constant) ∼ 760 (τ/ms) −0.5 mJy rms sensitivity.

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Section: Introductionmentioning

confidence: 75%

The Northern Cross fast radio burst project – I. Overview and pilot observations at 408 MHz

Locatelli

Bernardi

Bianchi

et al. 2020

Monthly Notices of the Royal Astronomical Society

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“…In such cases, we adopt the reported duration as an intrinsic duration, w int , instead of our calculation. The spec-z flag is for four FRBs with spectroscopic redshift measured from the host galaxies (FRB 121102, 180916.J0158+65, 180924, and 190523;Tendulkar et al 2017;Marcote et al 2020;Bannister et al 2019;. For these four FRBs we use the spectroscopic redshifts instead of the redshift estimated from the dispersion measure.…”

Section: Samplementioning

confidence: 99%

“…As a conservative estimate, we adopted the highest uncertainty of DM IGM (z), δDM IGM (z), among simulations with different resolutions (Zhu et al 2018). We used spectroscopic redshift instead of DM-derived redshift if available (i.e., FRB121102, 180916.J0158+65, 180924, and 190523: Tendulkar et al 2017;Marcote et al 2020;Bannister et al 2019;). We calculated time-integrated luminosities of FRBs at rest-frame 1.83 GHz by using Eq.…”

Section: Time-integrated Luminositymentioning

confidence: 99%

Luminosity–duration relations and luminosity functions of repeating and non-repeating fast radio bursts

Hashimoto

Goto

Wang

et al. 2020

Monthly Notices of the Royal Astronomical Society

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Fast radio bursts (FRBs) are mysterious radio bursts with a time scale of approximately milliseconds. Two populations of FRB, namely repeating and non-repeating FRBs, are observationally identified. However, the differences between these two and their origins are still cloaked in mystery. Here we show the time-integrated luminosityduration (L ν -w int,rest ) relations and luminosity functions (LFs) of repeating and nonrepeating FRBs in the FRB Catalogue project. These two populations are obviously separated in the L ν -w int,rest plane with distinct LFs, i.e., repeating FRBs have relatively fainter L ν and longer w int,rest with a much lower LF. In contrast with non-repeating FRBs, repeating FRBs do not show any clear correlation between L ν and w int,rest . These results suggest essentially different physical origins of the two. The faint ends of the LFs of repeating and non-repeating FRBs are higher than volumetric occurrence rates of neutron-star mergers and accretion-induced collapse (AIC) of white dwarfs, and are consistent with those of soft gamma-ray repeaters (SGRs), type Ia supernovae, magnetars, and white-dwarf mergers. This indicates two possibilities: either (i) faint non-repeating FRBs originate in neutron-star mergers or AIC and are actually repeating during the lifetime of the progenitor, or (ii) faint non-repeating FRBs originate in any of SGRs, type Ia supernovae, magnetars, and white-dwarf mergers. The bright ends of LFs of repeating and non-repeating FRBs are lower than any candidates of progenitors, suggesting that bright FRBs are produced from a very small fraction of the progenitors regardless of the repetition. Otherwise, they might originate in unknown progenitors.

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“…It is firmly established that at least a few milli-second duration, very bright, radio signals that have been detected between about 400 MHz and 7 GHz (known as Fast Radio Bursts or FRBs) are coming from a distance of about a Gpc or more, eg. Lorimer et al 2007; Thornton et al 2013;Spitler et al 2014;Petroff et al 2016;Bannister et al 2017;Law et al 2017;Chatterjee et al 2017;Marcote et al 2017;Tendulkar et al 2017;Gajjar et al 2018;Michilli et al 2018;Farah et al 2018;Shannon et al 2018;Oslowski et al 2019;Kocz et al 2019;Bannister et al 2019;CHIME Collaboration 2019a and2019b;Ravi 2019aRavi , 2019bRavi et al 2019. Many mechanisms have been suggested for the generation of high luminosity coherent radio waves from Fast Radio Bursts (FRBs), eg. Katz (2014Katz ( , 2016, Murase et al (2016;, Kumar et al (2017), Metzger et al (2017), Zhang (2017), Beloborodov (2017), Cordes (2017), Ghisellini & Locatelli (2018), Lu & Kumar (2018), Metzger et al (2019), Thompson (2019), Wang & Lai (2019), ; for a recent review see Katz (2018).…”

Section: Introductionmentioning

confidence: 99%

FRB coherent emission from decay of Alfvén waves

Kumar

Bošnjak

2020

Monthly Notices of the Royal Astronomical Society

101

107

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We present a model for FRBs where a large amplitude Alfvén wave packet is launched by a disturbance near the surface of a magnetar, and a substantial fraction of the wave energy is converted to coherent radio waves at a distance of a few tens of neutron star radii. The wave amplitude at the magnetar surface should be about 10 11 G in order to produce a FRB of isotropic luminosity 10 44 erg s −1 . An electric current along the static magnetic field is required by Alfvén waves with non-zero component of transverse wave-vector. The current is supplied by counter-streaming electron-positron pairs, which have to move at nearly the speed of light at larger radii as the plasma density decreases with distance from the magnetar surface. The counter-streaming pairs are subject to two-stream instability which leads to formation of particle bunches of size of order c/ω p ; where ω p is plasma frequency. A strong electric field develops along the static magnetic field when the wave packet arrives at a radius where electron-positron density is insufficient to supply the current required by the wave. The electric field accelerates particle bunches along the curved magnetic field lines, and that produces the coherent FRB radiation. We provide a number of predictions of this model.

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A single fast radio burst localized to a massive galaxy at cosmological distance

Cited by 390 publications

References 87 publications

The Northern Cross fast radio burst project – I. Overview and pilot observations at 408 MHz

The Northern Cross fast radio burst project – I. Overview and pilot observations at 408 MHz

Luminosity–duration relations and luminosity functions of repeating and non-repeating fast radio bursts

FRB coherent emission from decay of Alfvén waves

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