INTEGRAL Discovery of a Burst with Associated Radio Emission from the Magnetar SGR 1935+2154

Mereghetti, S.; Savchenko, V.; Ferrigno, C.; Götz, D.; Rigoselli, Michela; Tiengo, A.; Bazzano, A.; Bozzo, E.; Coleiro, A.; Courvoisier, T. J. L.; Doyle, Maeve; Goldwurm, A.; Hanlon, L.; Jourdain, E.; Kienlin, A. von; Lutovinov, A.; Martín-Carrillo, A.; Molkov, S.; Natalucci, L.; Onori, F.; Panessa, F.; Rodi, J.; Rodríguez, J.; Sánchez–Fernández, C.; Sunyaev, R.; Ubertini, P.

doi:10.3847/2041-8213/aba2cf

Cited by 326 publications

(303 citation statements)

References 59 publications

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“…As the only other X-ray burst from SGR 1935+2154 that has been reported with a multiwavelength (radio) counterpart, we compare the NIR limits to the observed spectral energy distribution (SED) of FRB 200428. The striking time coincidence between two X-ray pulses observed in the X-ray burst associated with FRB 200428 (Li et al 2020a;Mereghetti et al 2020) with the two radio pulses detected by CHIME (The CHIME/FRB Collaboration et al 2020) potentially suggests a common emission source extending from the X-ray to radio frequencies. Li et al (2020a) show that the HXMT X-ray burst associated FRB 200428 was characterized with a hard powerlaw spectrum with a photon index of Γ≈1.5, corresponding to a flux density dependence of f ν ∝ν −0.5 and fluence dependence of n µ  0.5 .…”

Section: Comparison To the Multiwavelength Properties Of Frb 200428mentioning

confidence: 92%

Constraining the X-Ray–Infrared Spectral Index of Second-timescale Flares from SGR 1935+2154 with Palomar Gattini-IR

Ashley

Andreoni

et al. 2020

ApJL

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The Galactic magnetar SGR 1935+2154 has been reported to produce the first example of a bright millisecondduration radio burst (FRB 200428) similar to the cosmological population of fast radio bursts (FRBs). The detection of a coincident bright X-ray burst represents the first observed multiwavelength counterpart of an FRB. However, the search for similar emission at optical wavelengths has been hampered by the high inferred extinction on the line of sight. Here, we present results from the first search for second-timescale emission from the source at near-infrared (NIR) wavelengths using the Palomar Gattini-IR observing system in the J band, enabled by a novel detector readout mode that allows short exposure times of ≈0.84 s with 99.9% observing efficiency. With a total observing time of ≈12 hr (≈47,728 images) during its 2020 outburst, we place median 3σ limits on the secondtimescale NIR fluence of 18Jy ms (13.1 AB mag). The corresponding extinction-corrected limit is 125Jy ms for an estimated extinction of A J =2.0 mag. Our observations were sensitive enough to easily detect an NIR counterpart of FRB 200428 if the NIR emission falls on the same power law as observed across its radio to X-ray spectrum. We report nondetection limits from epochs of four simultaneous X-ray bursts detected by the Insight-HXMT and NuSTAR telescopes during our observations. These limits provide the most stringent constraints to date on fluence of flares at ∼10 14 Hz, and constrain the fluence ratio of the NIR emission to coincident X-ray bursts to R NIR 0.025 (fluence index 0.35).

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Section: Comparison To the Multiwavelength Properties Of Frb 200428mentioning

confidence: 92%

Constraining the X-Ray–Infrared Spectral Index of Second-timescale Flares from SGR 1935+2154 with Palomar Gattini-IR

Ashley

Andreoni

et al. 2020

ApJL

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“…The observational situation changed abruptly with the recent discovery of a luminous millisecond radio burst from the Galactic magnetar SGR 1935+2154 (Bochenek et al 2020c;CHIME/FRB Collaboration et al 2020b). The double-peaked burst, detected independently by CHIME (Bandura et al 2014) and STARE2 (Bochenek et al 2020b), was temporally coincident with an X-ray burst of significantly larger fluence Mereghetti et al 2020a;Ridnaia et al 2020e;Tavani et al 2020). This FRB is still a factor of ∼10 less energetic than the weakest FRB previously detected from any localized cosmological FRB source.…”

Section: Introductionmentioning

confidence: 92%

“…The source is associated with supernova remnant (SNR) G57.2+0.8 (Gaensler 2014). Distance estimates are uncertain, ranging from 4.4 to 12.5 kpc (Sun et al 2011;Pavlović et al 2013;Kothes et al 2018;Mereghetti et al 2020a;Zhou et al 2020), and throughout this paper, we adopt a distance of = d d 10 kpc…”

Section: Sgr 1935+2154mentioning

confidence: 99%

“…This burst's long duration of~1.7 s and large fluence of´-2.5 10 5 erg cm −2 (radiated energy~10 41 erg) place it in the rare class of "intermediate" SGR flares (Mazets et al 1999;Feroci et al 2003;Mereghetti et al 2009;Göǧüś et al 2011). The trend that the bursts from SGR 1935+2154 have become progressively more energetic in the years since its initial discovery (Younes et al 2017) persists with the recent outburst, which is the most energetic yet (Mereghetti et al 2020a;Zhang et al 2020a). Similar behavior was previously observed for SGR1806-20, which culminated with its production of the most energetic magnetar giant flare seen to date (Younes et al 2015).…”

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confidence: 98%

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Implications of a Fast Radio Burst from a Galactic Magnetar

Margalit

Beniamini

Sridhar

et al. 2020

ApJL

148

115

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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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“…However, the origin of FRBs remains an unsolved puzzle. The nature of the underlying object has been identified to be magnetars only very recently by observing a FRB in the Galaxy in the radio and X-ray bands simultaneously (The CHIME/FRB Collaboration et al 2020;Bochenek et al 2020;Mereghetti et al 2020;Li et al 2020;Pearlman et al 2020;Ridnaia et al 2020;Tavani et al 2020). Although this observation is a major landmark for FRB science, many emission models remain valid (Lu et al 2020;Lyutikov & Popov 2020;Margalit et al 2020a;Katz 2020).…”

Section: Introductionmentioning

confidence: 99%

What does FRB light-curve variability tell us about the emission mechanism?

Beniamini

Kumar

2020

Monthly Notices of the Royal Astronomical Society

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A few fast radio bursts’ (FRBs) light-curves have exhibited large intrinsic modulations of their flux on extremely short (tr ∼ 10μs) time scales, compared to pulse durations (tFRB ∼ 1ms). Light-curve variability timescales, the small ratio of rise time of the flux to pulse duration, and the spectro-temporal correlations in the data constrain the compactness of the source and the mechanism responsible for the powerful radio emission. The constraints are strongest when radiation is produced far (≳ 1010cm) from the compact object. We describe different physical set-ups that can account for the observed tr/tFRB ≪ 1 despite having large emission radii. The result is either a significant reduction in the radio production efficiency or distinct light-curves features that could be searched for in observed data. For the same class of models, we also show that due to high-latitude emission, if a flux f1(ν1) is observed at t1 then at a lower frequency ν2 < ν1 the flux should be at least (ν2/ν1)2f1 at a slightly later time (t2 = t1ν1/ν2) independent of the duration and spectrum of the emission in the comoving frame. These features can be tested, once light-curve modulations due to scintillation are accounted for. We provide the timescales and coherence bandwidths of the latter for a range of possibilities regarding the physical screens and the scintillation regime. Finally, if future highly resolved FRB light-curves are shown to have intrinsic variability extending down to ∼μs timescales, this will provide strong evidence in favor of magnetospheric models.

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INTEGRAL Discovery of a Burst with Associated Radio Emission from the Magnetar SGR 1935+2154

Cited by 326 publications

References 59 publications

Constraining the X-Ray–Infrared Spectral Index of Second-timescale Flares from SGR 1935+2154 with Palomar Gattini-IR

Constraining the X-Ray–Infrared Spectral Index of Second-timescale Flares from SGR 1935+2154 with Palomar Gattini-IR

Implications of a Fast Radio Burst from a Galactic Magnetar

What does FRB light-curve variability tell us about the emission mechanism?

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