Periodic activity from a fast radio burst source

Chime,; Amiri, M.; Andersen, Bridget C.; Bandura, Kevin; Bhardwaj, Mohit; Boyle, Patrick J.; Brar, Charanjot; Chawla, Pragya; Chen, Tianyue; Cliche, J. F.; Čubranić, Davor; Deng, Meiling; Denman, Nolan; Dobbs, M.; Dong, Fengqiu Adam; Fandino, Mateus; Fonseca, Emmanuel; Gaensler, B. M.; Giri, Utkarsh; Good, Deborah C.; Halpern, M.; Hessels, J. W. T.; Hill, Alex S.; Höfer, Carolin; Josephy, Alexander; Kania, Joseph; Karuppusamy, R.; Kaspi, V. M.; Keimpema, A.; Kirsten, F.; Landecker, T. L.; Lang, Dustin; Leung, Calvin; Li, D. Z.; Lin, HaiNan; Marcote, B.; Masui, Kiyoshi; Mckinven, Ryan; Mena-Parra, Juan; Merryfield, Marcus; Michilli, D.; Milutinović, Nikola; Mirhosseini, Arash; Naidu, Arun; Newburgh, Laura; Ng, Cherry; Nimmo, K.; Paragi, Z.; Patel, C.; Pen, Ue-Li; Pinsonneault-Marotte, Tristan; Pleunis, Ziggy; Rafiei-Ravandi, Masoud; Rahman, Mubdi; Ransom, S. M.; Rénard, A.; Sanghavi, Pranav; Scholz, Paul; Shaw, J. Richard; Shin, Kaitlyn; Siegel, Seth R.; Singh, Saurabh; Smegal, Rick; Smith, Kendrick M.; Stairs, I. H.; Tendulkar, Shriharsh P.; Tretyakov, Ian; Vanderlinde, K.; Wang, H.; Wang, X.; Wulf, Dallas; Yadav, Prakarsh; Zwaniga, A. V.

doi:10.1038/s41586-020-2398-2

Cited by 283 publications

(186 citation statements)

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“…A particularly interesting discovery reported by the CHIME/ FRB Collaboration is the repeating source FRB 180916. J0158+65, which shows a 16.35 day modulation in its burst activity (CHIME/FRB Collaboration et al 2020). In Spring 2020, follow-up observations of FRB 180916.J0158+65 in the 300−400 MHz frequency range (Chawla et al 2020;Pilia et al 2020) provided the lowest-frequency detections of FRBs to date.…”

Section: Introductionmentioning

confidence: 97%

First Discovery of a Fast Radio Burst at 350 MHz by the GBNCC Survey

Parent

Chawla

Kaspi

et al. 2020

ApJ

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We report the first discovery of a fast radio burst (FRB), FRB 20200125A, by the Green Bank Northern Celestial Cap (GBNCC) Pulsar Survey conducted with the Green Bank Telescope at 350 MHz. FRB 20200125A was detected at a Galactic latitude of 58°. 43 with a dispersion measure of 179 pc cm 3 , while electron density models predict a maximum Galactic contribution of 25 pc cm 3 along this line of sight. Moreover, no apparent Galactic foreground sources of ionized gas that could account for the excess DM are visible in multiwavelength surveys of this region. This argues that the source is extragalactic. The maximum redshift for the host galaxy is z max =0.17, corresponding to a maximum comoving distance of approximately 750 Mpc. The measured peak flux density for FRB 20200125A is 0.37 Jy, and we measure a pulse width of 3.7 ms, consistent with the distribution of FRB widths observed at higher frequencies. Based on this detection and assuming a Euclidean flux density distribution of FRBs, we calculate an all-sky rate at 350 MHz of-+ 3.4 10 3.3 15.43 FRBs sky −1 day −1 above a peak flux density of 0.42 Jy for an unscattered pulse having an intrinsic width of 5 ms, consistent with rates reported at higher frequencies, albeit with large uncertainties. Given the recent improvements in our single-pulse search pipeline, we also revisit the GBNCC survey sensitivity to various burst properties. Finally, we find no evidence of strong interstellar scattering in FRB 20200125A, adding to the growing evidence that some FRBs have circumburst environments where free-free absorption and scattering are not significant.

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Section: Introductionmentioning

confidence: 97%

First Discovery of a Fast Radio Burst at 350 MHz by the GBNCC Survey

Parent

Chawla

Kaspi

et al. 2020

ApJ

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“…The recurrent FRB 180916 was recently shown by the CHIME/ FRB collaboration to exhibit a 16 day period of unknown origin (CHIME/FRB Collaboration et al 2020a). Again, although known Galactic magnetars offer no clear explanation for periodic behavior at this scale (with the possible exception of candidate magnetar 1E 1613485055, which has a measured period of 6.7 hr; de Luca et al 2006), reasonable variations in the properties of extragalactic magnetars (e.g., extremely slow rotation, precession, or presence in a binary) offer a potential explanation (Beniamini et al 2020;Levin et al 2020;Lyutikov et al 2020;Tong et al 2020;Yang & Zou 2020;Zanazzi & Lai 2020).…”

Section: Introductionmentioning

confidence: 99%

“…(yellow; Law et al 2017; Gourdji et al 2019), the recently localized CHIME repeater FRB180916 (purple; Marcote et al 2020; CHIME/FRB Collaboration et al 2020a), and the apparently nonrepeating FRBs180924 (green, upper limits denoted by upside-down triangles; Bannister et al 2019), 190523 (brown; Ravi 2019), and 181112 (blue;Prochaska et al 2019). We have used quoted rates where possible(Law et al 2017;Gourdji et al 2019;CHIME/FRB Collaboration et al 2020a) and otherwise estimated Poissonian rates based on quoted field exposure times where available.…”

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confidence: 99%

Implications of a Fast Radio Burst from a Galactic Magnetar

Margalit

Beniamini

Sridhar

et al. 2020

ApJL

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A luminous radio burst was recently detected in temporal coincidence with a hard X-ray flare from the Galactic magnetar SGR 1935+2154with a time and frequency structure consistent with cosmological fast radio bursts (FRBs) and a fluence within a factor of 10 of the least energetic extragalactic FRB previously detected. Although active magnetars are commonly invoked FRB sources, several distinct mechanisms have been proposed for generating the radio emission that make different predictions for the accompanying higher-frequency radiation. We show that the properties of the coincident radio and X-ray flares from SGR 1935+2154, including their approximate simultaneity and relative fluence~-E E 10 radio X 5 , as well as the duration and spectrum of the X-ray emission, are consistent with extant predictions for the synchrotron maser shock model. Rather than arising from the inner magnetosphere, the X-rays are generated by (incoherent) synchrotron radiation from thermal electrons heated at the same internal shocks that produce the coherent maser emission as ultrarelativistic flare ejecta collides with a slower particle outflow (e.g., as generated by earlier flaring activity) on a radial scale of~10 11 cm. Although the rate of SGR 1935+2154-like bursts in the local universe is not sufficient to contribute appreciably to the extragalactic FRB rate, the inclusion of an additional population of more active magnetars with stronger magnetic fields than the Galactic population can explain both the FRB rate and the repeating fraction, but only if the population of active magnetars are born at a rate that is at least 2 orders of magnitude lower than that of the SGR 1935+2154-like magnetars. This may imply that the more active magnetar sources are not younger magnetars formed in a similar way to the Milky Way population (e.g., via ordinary supernovae) but are instead formed through more exotic channels, such as superluminous supernovae, accretion-induced collapse, or neutron star mergers.

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“…Over the past few years, daily radio observations of the northern hemisphere sky in the 400-800 MHz frequency band with the Canadian Hydrogen Intensity Mapping Experi-ment(CHIME) transit radio telescope have led to discovery of many new repeatingFRB sources (The CHIME/FRB Collaboration et al 2019aFonseca et al 2020), enabled by the instrument's large instantaneous field of view(FoV), wide bandwidth, and high sensitivity (The CHIME/FRB Collaboration et al 2018). In particular, the discovery of FRB180916.J0158+65(also referred to as FRB 20180916B; The CHIME/FRB Collaboration et al 2019b), its subsequent localization to a nearby massive spiral galaxy (Marcote et al 2020), and the detection of a 16.35 day periodicity (or possibly a higher frequency alias of this period) in the burst arrival times (The CHIME/FRB Collaboration et al 2020a) have facilitated detailed studies of the source via follow-up observations across multiple wavelengths(e.g., see Scholz et al 2020;Tendulkar et al 2020). Most bursts from FRB180916.J0158+65 have been detected within a ∼5.4 day interval during cycles when the source was observed to be active (e.g., see Chawla et al 2020;Marthi et al 2020;Pilia et al 2020;Sand et al 2020;The CHIME/FRB Collaboration et al 2020a), but some bursts have been found to occur slightly outside this activity window (e.g., see Aggarwal & Realfast Collaboration 2020).…”

Section: Introductionmentioning

confidence: 99%

Multiwavelength Radio Observations of Two Repeating Fast Radio Burst Sources: FRB 121102 and FRB 180916.J0158+65

Pearlman

Majid

Prince

et al. 2020

ApJL

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The spectra of fast radio bursts (FRBs) encode valuable information about the source's local environment, underlying emission mechanism(s), and the intervening media along the line of sight. We present results from a long-term multiwavelength radio monitoring campaign of two repeating FRB sources, FRB121102 and FRB180916.J0158 +65, with the NASA Deep Space Network(DSN) 70 m radio telescopes (DSS-63 and DSS-14). The observations of FRB121102 were performed simultaneously at 2.3 and 8.4 GHz, and spanned a total of 27.3 hr between 2019September19 and 2020February11. We detected tworadio bursts in the 2.3 GHz frequency band from FRB121102, but no evidence of radio emission was found at 8.4 GHz during any of our observations. We observed FRB180916.J0158+65 simultaneously at 2.3 and 8.4 GHz, and also separately in the 1.5 GHz frequency band, for a total of 101.8 hr between 2019September19 and 2020May14. Our observations of FRB180916.J0158+65 spanned multiple activity cycles during which the source was known to be active and covered a wide range of activity phases. Several of our observations occurred during times when bursts were detected from the source between 400 and 800 MHz with the Canadian Hydrogen Intensity Mapping Experiment(CHIME) radio telescope. However, no radio bursts were detected from FRB180916.J0158+65 at any of the frequencies used during our observations with the DSNradio telescopes. We find that FRB180916.J0158+65ʼs apparent activity is strongly frequency-dependent due to the narrowband nature of its radio bursts, which have less spectral occupancy at high radio frequencies ( 2 GHz). We also find that fewer or fainter bursts are emitted from the source at high radio frequencies. We discuss the implications of these results for possible progenitor models of repeating FRBs.

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Periodic activity from a fast radio burst source

Cited by 283 publications

References 55 publications

First Discovery of a Fast Radio Burst at 350 MHz by the GBNCC Survey

First Discovery of a Fast Radio Burst at 350 MHz by the GBNCC Survey

Implications of a Fast Radio Burst from a Galactic Magnetar

Multiwavelength Radio Observations of Two Repeating Fast Radio Burst Sources: FRB 121102 and FRB 180916.J0158+65

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