Late Time Afterglow Observations Reveal a Collimated Relativistic Jet in the Ejecta of the Binary Neutron Star Merger GW170817

Lazzati, Davide; Perna, Rosalba; Morsony, Brian J.; López-Cámara, Diego; Cantiello, Matteo; Ciolfi, R.; Giacomazzo, B.; Workman, Jared C.

doi:10.1103/physrevlett.120.241103

Cited by 347 publications

(336 citation statements)

References 64 publications

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“…When jets plow through dense environments they deposit a fraction of their energy in a hot cocoon (Ramirez-Ruiz et al 2002;Pe'er et al 2006), which may occur in binary neutron star mergers as the ultrarelativistic jet that powers the SGRB pushes through material ejected just before merger (Lazzati et al 2017). GRB 170817A has odd behavior in both prompt and afterglow emission, the origin of which is a matter of some debate (Abbott et al 2017a;Alexander et al 2017Alexander et al , 2018Bromberg et al 2017;Haggard et al 2017;Kasliwal et al 2017;Margutti et al 2017;Mooley et al 2018aMooley et al , 2018bTroja et al 2017Troja et al , 2018aGottlieb et al 2018;Lazzati et al 2018;Lyman et al 2018;Nynka et al 2018;Ruan et al 2018;Veres et al 2018). Possible interpretations include a structured ultrarelativistic jet (e.g., Alexander et al 2018), a jet and cocoon together (e.g., Abbott et al 2017a), or a cocoon model (e.g., Kasliwal et al 2017) where the shock breakout produces the harder peak.…”

Section: The Origin Of the Soft Tailmentioning

confidence: 99%

Fermi GBM Observations of GRB 150101B: A Second Nearby Event with a Short Hard Spike and a Soft Tail

Burns

Vereš

Connaughton

et al. 2018

ApJL

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In light of the joint multimessenger detection of a binary neutron star merger as the gamma-ray burst GRB 170817A and in gravitational waves as GW170817, we reanalyze the Fermi Gamma-ray Burst Monitor data of one of the closest short gamma-ray bursts (SGRBs): GRB 150101B. We find that this burst is composed of a short hard spike followed by a comparatively long soft tail. This apparent two-component nature is phenomenologically similar to that of GRB 170817A. While GRB 170817A was distinct from the previously known population of SGRBs in terms of its prompt intrinsic energetics, GRB 150101B is not. Despite these differences, GRB 150101B can be modeled as a more on-axis version of GRB 170817A. Identifying a similar signature in two of the closest SGRBs suggests that the soft tail is common, but generally undetectable in more distant events. If so, it will be possible to identify nearby SGRBs from the prompt gamma-ray emission alone, aiding the search for kilonovae.

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Section: The Origin Of the Soft Tailmentioning

confidence: 99%

Fermi GBM Observations of GRB 150101B: A Second Nearby Event with a Short Hard Spike and a Soft Tail

Burns

Vereš

Connaughton

et al. 2018

ApJL

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“…While short GRBs can be observed to cosmological distances, they are believed to be rather tightly beamed, so that only a small fraction of BNS mergers would be accompanied by a gamma ray burst (GRB) counterpart [126]. However, observations of GW170817 imply that the gamma ray burst (GRB) emission is structured [25] with a broader, weak emission, possibly powered by a cocoon [47,127,128]. Since the gamma ray burst (GRB) emission is likely to be essentially concurrent with the merger, it will be difficult to use GW observations to provide advanced warning to gamma ray burst (GRB) satellites.…”

Section: Implication For Em Follow-upmentioning

confidence: 99%

Localization of binary neutron star mergers with second and third generation gravitational-wave detectors

Mills¹,

Tiwari²,

Fairhurst³

2018

Phys. Rev. D

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The observation of gravitational wave signals from binary black hole and binary neutron star mergers has established the field of gravitational wave astronomy. It is expected that future networks of gravitational wave detectors will possess great potential in probing various aspects of astronomy. An important consideration for successive improvement of current detectors or establishment on new sites is knowledge of the minimum number of detectors required to perform precision astronomy. We attempt to answer this question by assessing the ability of future detector networks to detect and localize binary neutron stars mergers on the sky. Good localization ability is crucial for many of the scientific goals of gravitational wave astronomy, such as electromagnetic follow-up, measuring the properties of compact binaries throughout cosmic history, and cosmology. We find that although two detectors at improved sensitivity are sufficient to get a substantial increase in the number of observed signals, at least three detectors of comparable sensitivity are required to localize majority of the signals, typically to within around 10 deg 2 -adequate for follow-up with most wide field of view optical telescopes.

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“…The first one assumes that the emission was intrinsically sub-luminous and quasi-isotropic [58,59]. The second one assumes instead a standard short GRB emission, that was observed off-axis [60]. While at the moment, about a hundred days after the event, both possibilities can explain the data, the analysis of the future time-evolution of the synchrotron emission will ultimately be able to distinguish between these two scenarios, telling therefore if GRB170817A was a standard short GRB seen off-axis or if it belongs to a new class of phenomena [61].…”

Section: The Weak Gamma Emission Of Grb170817a: Was It a Standard Shomentioning

confidence: 99%

The Merger of Two Compact Stars: A Tool for Dense Matter Nuclear Physics

et al. 2018

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Abstract:We discuss the different signals, in gravitational and electromagnetic waves, emitted during the merger of two compact stars. We will focus in particular on the possible contraints that those signals can provide on the equation of state of dense matter. Indeed, the stiffness of the equation of state and the particle composition of the merging compact stars strongly affect, e.g., the life time of the post-merger remnant and its gravitational wave signal, the emission of the short gamma-ray-burst, the amount of ejected mass and the related kilonova. The first detection of gravitational waves from the merger of two compact stars in August 2017, GW170817, and the subsequent detections of its electromagnetic counterparts, GRB170817A and AT2017gfo, is the first example of the era of "multi-messenger astronomy": we discuss what we have learned from this detection on the equation of state of compact stars and we provide a tentative interpretation of this event, within the two families scenario, as being due to the merger of a hadronic star with a quark star.

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Late Time Afterglow Observations Reveal a Collimated Relativistic Jet in the Ejecta of the Binary Neutron Star Merger GW170817

Cited by 347 publications

References 64 publications

Fermi GBM Observations of GRB 150101B: A Second Nearby Event with a Short Hard Spike and a Soft Tail

Fermi GBM Observations of GRB 150101B: A Second Nearby Event with a Short Hard Spike and a Soft Tail

Localization of binary neutron star mergers with second and third generation gravitational-wave detectors

The Merger of Two Compact Stars: A Tool for Dense Matter Nuclear Physics

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