Challenging gamma-ray burst models through the broadband dataset of GRB 060908

Covino, S.; Campana, S.; Conciatore, M. L.; D’Elia, V.; Palazzi, E.; Thöne, C. C.; Vergani, S. D.; Wiersema, K.; Brusasca, M.; Cucchiara, A.; Cobb, B. E.; Fernández-Soto, A.; Канн, Д. А.; Malesani, D.; Tanvir, N. R.; Antonelli, L. A.; Bremer, M.; Castro-Tirado, A. J.; Postigo, A. de Ugarte; Molinari, E.; Nicastro, L.; Stefanon, Mauro; Testa, V.; Tosti, G.; Vitali, F.; Amati, L.; Chapman, R. W.; Conconi, P.; Cutispoto, G.; Fynbo, J. P. U.; Goldoni, P.; Henriksen, C.; Horne, K.; Malaspina, G.; Meurs, E. J. A.; Pian, E.; Stella, L.; Tagliaferri, G.; Ward, Paul A. S.; Zerbi, F. M.

doi:10.1051/0004-6361/201014994

Cited by 28 publications

(25 citation statements)

References 114 publications

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“…The origin of the hard electron distribution (p < 2) is not yet clear. The observations also confirmed the evidence for hard electron distribution in some GRBs (Dai & Cheng 2001;Huang et al 2006;Covino et al 2010). Simulations of the Fermi process in relativistic shocks including large angle scattering have resulted in hard electron energy spectra (Stecker, Baring & Summerlin 2007).…”

Section: Conclusion and Discussionsupporting

confidence: 83%

Long-term X-ray emission from Swift J1644+57

Zou¹,

Wang²,

Cheng

2013

Monthly Notices of the Royal Astronomical Society

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The X-ray emission from Swift J1644+57 is not steadily decreasing instead it shows multiple pulses with declining amplitudes. We model the pulses as reverse shocks from collisions between the late ejected shells and the externally shocked material, which is decelerated while sweeping the ambient medium. The peak of each pulse is taken as the maximum emission of each reverse shock. With a proper set of parameters, the envelope of peaks in the light curve as well as the spectrum can be modelled nicely.

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Section: Conclusion and Discussionsupporting

confidence: 83%

Long-term X-ray emission from Swift J1644+57

Zou¹,

Wang²,

Cheng

2013

Monthly Notices of the Royal Astronomical Society

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“…This is not unprecedented behaviour, as very blue optical spectra have been previously reported (e.g. for GRB 060908, Covino et al 2010). The optical spectral slope and rest-frame extinction show a high degree of degeneracy.…”

Section: Analysis Of the Afterglow Emissionsupporting

confidence: 70%

GRB 091127/SN 2009nz and the VLT/X-shooter spectroscopy of its host galaxy: probing the faint end of the mass-metallicity relation

Vergani

Flores

Covino

et al. 2011

A&A

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We perform a detailed study of the gamma-ray burst GRB 091127/SN 2009nz host galaxy at z = 0.490 using the VLT/X-shooter spectrograph in slit and integral-field unit (IFU) mode. From the analysis of the optical and X-ray afterglow data obtained from ground-based telescopes and Swift-XRT, we confirm the presence of a bump associated with SN 2009nz and find evidence of a possible jet break in the afterglow lightcurve. The X-shooter afterglow spectra reveal several emission lines from the underlying host, from which we derive its integrated properties. These properties agree with those of previously studied GRB-SN hosts and, more generally, with those of the long GRB host population. We use the Hubble Space Telescope and ground-based images of the host to determine its stellar mass (M ). Our results extend to lower M values the M-Z plot derived for the sample of long GRB hosts at 0.3 < z < 1.0 adding new information to probe the faint end of the M-Z relation and the shift of the LGRB host M-Z relation from that found from emission-line galaxy surveys. Thanks to the IFU spectroscopy, we can build the two-dimensional (2D) velocity, velocity dispersion, and star formation rate (SFR) maps. They show that the host galaxy has perturbed rotation kinematics with evidence of a SFR enhancement consistent with the afterglow position.

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“…Several GRBs exhibit a similar light curve flattening from α opt,1 ∼ 1.3 − 1.6 to α opt,2 ∼ 0.8 − 1.1 in the optical at early times; see Table 4: GRB 021211 (Fox et al 2003), GRB 050525A (Shao & Dai 2005), GRB 050904 (Haislip et al 2006;Wei et al 2006), GRB 060908 (Covino et al 2010), GRB 061126 (Gomboc et al 2008;Perley et al 2008), GRB 090102 (Steele et al 2009;Gendre et al 2010), GRB 090424 (Jin et al 2013) and GRB 090902B (Pandey et al 2010). Additionally, most of them bear similar spectral and temporal properties to GRB 190114C in both optical and X-rays regimes.…”

Section: Modeling the Optical Afterglowmentioning

confidence: 89%

Lowly Polarized Light from a Highly Magnetized Jet of GRB 190114C

Jordana-Mitjans

Mundell

Kobayashi

et al. 2020

ApJ

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We report multi-color optical imaging and polarimetry observations of the afterglow of the first TeVdetected gamma-ray burst, GRB 190114C, using the RINGO3 polarimeter on the 2-m autonomous robotic Liverpool Telescope. Observations begin 201 s after the onset of the GRB and continue until ∼ 7000 s post-burst. High temporal resolution (∆t 2.3 − 4.6 s) and dense sampling of the RINGO3 light curves reveal a chromatic break at t ∼ 400 − 500 s -with initial temporal decay α ∼ 1.5 flattening to α ∼ 1 post-break -which we model as a combination of reverse and forward-shock components, with magnetization parameter R B ∼ 40. The observed polarization degree P ∼ 2 − 4% remains steady throughout the first ∼ 2000-s observation window, with a constant position angle. Broadband spectral energy distribution modeling of the afterglow confirms GRB 190114C is highly obscured (A v,HG = 1.49 ± 0.12 mag; N H,HG = (9.0 ± 0.03) × 10 22 cm −2 ). The measured polarization is therefore dominated by dust scattering and the intrinsic polarization is low -in contrast to P > 10% measured previously for other GRB reverse shocks. We test whether 1st and higher-order inverse Compton scattering in a magnetized reverse shock can explain the low optical polarization and the sub-TeV emission but conclude neither is explained in the reverse shock Inverse Compton model. Instead, the unexpectedly low intrinsic polarization degree in GRB 190114C can be explained if largescale jet magnetic fields are distorted on timescales prior to reverse shock emission.

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Challenging gamma-ray burst models through the broadband dataset of GRB 060908

Cited by 28 publications

References 114 publications

Long-term X-ray emission from Swift J1644+57

Long-term X-ray emission from Swift J1644+57

GRB 091127/SN 2009nz and the VLT/X-shooter spectroscopy of its host galaxy: probing the faint end of the mass-metallicity relation

Lowly Polarized Light from a Highly Magnetized Jet of GRB 190114C

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