Early spectra of the gravitational wave source GW170817: Evolution of a neutron star merger

Shappee, B. J.; Simon, Joshua D.; Drout, M. R.; Piro, Anthony L.; Morrell, N.; Prieto, J. L.; Kasen, Daniel; Holoien, T. W. S.; Kollmeier, Juna A.; Kelson, Daniel D.; Coulter, D. A.; Foley, R. J.; Kilpatrick, C. D.; Siebert, M. R.; Madore, Barry F.; Murguia-Berthier, Ariadna; Pan, Y.-C.; Prochaska, J. Xavier; Ramírez-Ruiz, E.; Rest, A.; Adams, C.; Alatalo, Katherine; Bañados, Eduardo; Baughman, J.; Bernstein, R. A.; Bitsakis, T.; Boutsia, K.; Bravo, J.; Mille, F. Di; Higgs, Clare; Ji, Alexander P.; Maravelias, G.; Marshall, J. L.; Placco, Vinicius M.; Prieto, G.; Wan, Zhen

doi:10.1126/science.aaq0186

Cited by 294 publications

(249 citation statements)

References 55 publications

(98 reference statements)

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“…As one of the best sGRB events observed ever, GW170817 is rich in new data; E-mail: hamidani.hamid@yukawa.kyoto-u.ac.jp such as, the mass of the BNS (∼ 2.7M ; Abbott et al 2017a), the viewing angle (∼ 20 • − 30 • ; Abbott et al 2017a;Troja et al 2018), and the delay between the GW and the EM signal (∼ 1.7s; Abbott et al 2017a;Abbott et al 2017c), all inferred for the first time. Superluminal motion in late radio afterglow observations (Mooley et al 2018), and macronova/kilonova (hereafter macronova) emission with a strong support for r-process nucleosynthesis (Arcavi et al 2017;Chornock et al 2017;Coulter et al 2017;Díaz et al 2017;Drout et al 2017;Kilpatrick et al 2017;Kasliwal et al 2017;Nicholl et al 2017;Pian et al 2017;Smartt et al 2017;Shappee et al 2017;Soares-Santos et al 2017;Tanaka et al 2017;Utsumi et al 2017;Valenti et al 2017) are also new revelations. This event also had impacts on the equation of state of neutron stars, relativity, cosmology, etc.…”

Section: Introductionmentioning

confidence: 93%

“…So far, there has been no estimation of this calibration coefficient for the case of an expanding medium. Matsumoto & Kimura (2018); Salafia et al (2019) used the same calibration coefficient for the case of an expanding medium as an assumption, but offered no evidence. Here, after intense comparison with numerical simulations (in § 3), we found that Mizuta & Ioka (2013) and Harrison et al (2018) findings can be generalized for the case of an expanding medium; for the case of non-relativistic jet head propagation in an expanding medium, we show for the first time that this calibration coefficient is i) necessary and that ii) it takes roughly the same range of values as it does in the collapsar case.…”

Section: A Negligible Ambient Velocitymentioning

confidence: 99%

“…where t0 is time at which the jet is launched at r0, t − t0 is the time since the jet launch, rc is the lateral width of the cocoon, β ⊥ is the lateral average velocity of the expanding cocoon, β h = r h (t)−r 0 c(t−t 0 ) is the average jet head velocity, and Vc is the cocoon volume (we approximate the cocoon shape to an ellipsoidal: Vc = (2π/3)r 2 c r h (t)). η is a parameter that theoretically takes values between 0 and 1 (Bromberg et al 2011;Salafia et al 2019). η accounts for ignored effects such as the adiabatic expansion.…”

Section: Appendix A: Setup For the Analytic Modelmentioning

confidence: 99%

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Jet Propagation in Neutron Star Mergers and GW170817

Hamidani

Kiuchi

Ioka

2019

Monthly Notices of the Royal Astronomical Society

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The gravitational wave event from the binary neutron star (BNS) merger GW170817 and the following multi-messenger observations present strong evidence for i) merger ejecta expanding with substantial velocities and ii) a relativistic jet which had to propagate through the merger ejecta. The ejecta's expansion velocity is not negligible for the jet head motion, which is a fundamental difference from the other systems like collapsars and active galactic nuclei. Here we present an analytic model of the jet propagation in an expanding medium. In particular, we notice a new term in the expression of the breakout time and velocity. In parallel, we perform a series of over a hundred 2D numerical simulations of jet propagation. The BNS merger ejecta is prepared based on numerical relativity simulations of a BNS merger with the highestresolution to date. We show that our analytic results agree with numerical simulations over a wide parameter space. Then we apply our analytic model to GW170817, and obtain two solid constraints on: i) the central engine luminosity as L iso,0 ∼ 3 × 10 49 − 2.5 × 10 52 erg s −1 , and on ii) the delay time between the merger and engine activation t 0 − t m < 1.3 s. The engine power implies that the apparently-faint short gamma-ray burst (sGRB) sGRB 170817A is similar to typical sGRBs if observed on-axis.

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Section: Introductionmentioning

confidence: 93%

Section: A Negligible Ambient Velocitymentioning

confidence: 99%

Section: Appendix A: Setup For the Analytic Modelmentioning

confidence: 99%

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Jet Propagation in Neutron Star Mergers and GW170817

Hamidani

Kiuchi

Ioka

2019

Monthly Notices of the Royal Astronomical Society

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“…Figure 5 shows the rate of brightness change at λ rest ∼ 3400Å as a function of the absolute magnitude (based on the brighter of the two observations used for the rate estimate), while Figure 6 shows the absolute magnitude at λ rest ∼ 3400Å as a function of the time scale of the variability. Figure 7 diagram of other SNe and transients is derived from the u-and b-band light curves of nearby SNe obtained by the Swift Ultraviolet/Optical Telescope (UVOT) (Nugent et al 2011;Brown et al 2012;Pritchard et al 2014), the U -and B-band light curves of SN 1993J (Richmond et al 1994(Richmond et al , 1996, the g-and r-band light curves of PTF 09uj after the shock breakout obtained by PTF (Ofek et al 2010), the g-and r-band light curves of PS1-13arp after the shock breakout and rapid transients obtained by Pan-STARRS1 (Gezari et al 2015;Drout et al 2014), the g-and r-band light curves of the rapidly rising transients obtained by HSC (Tanaka et al 2016), uvw1-, u-, and g-band light curves of a fast luminous ultraviolet transient AT2018cow (Prentice et al 2018;Perley et al 2019), and U -, g-, and r-band light curves of a kilonova (AT2017gfo) associated with a gravitational wave source GW170817 (Andreoni et al 2017;Arcavi et al 2017;Coulter et al 2017;Cowperthwaite et al 2017;Díaz et al 2017;Drout et al 2017;Evans et al 2017;Valenti et al 2017;Kasliwal et al 2017;Pian et al 2017;Shappee et al 2017;Smartt et al 2017;Utsumi et al 2017, summarized in Villar et al 2017. We apply K-corrections by interpolating or extrapolating their spectral energy distributions in magnitude.…”

Section: Comparisons With Known Transientsmentioning

confidence: 99%

A Rapidly Declining Transient Discovered with the Subaru/Hyper Suprime-Cam

Tominaga

Morokuma

Tanaka

et al. 2019

ApJ

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We perform a high-cadence transient survey with Subaru Hyper Suprime-Cam (HSC), which we call the Subaru HSC survey Optimized for Optical Transients (SHOOT). We conduct HSC imaging observations with time intervals of about one hour on two successive nights, and spectroscopic and photometric follow-up observations. A rapidly declining blue transient SHOOT14di at z = 0.4229 is found in observations on two successive nights with an image subtraction technique. The rate of brightness change is +1.28 +0.40 −0.27 mag day −1 (+1.83 +0.57 −0.39 mag day −1 ) in the observer (rest) frame and the rest-frame color between 3400 and 4400Å is MThe nature of the object is investigated by comparing its peak luminosity, decline rate, and color with those of transients and variables previously observed, and those of theoretical models. None of the transients or variables share the same properties as SHOOT14di. Comparisons with theoretical models demonstrate that, while the emission from the cooling envelope of a Type IIb supernova shows a slower decline rate than SHOOT14di, and the explosion of a red supergiant star with a dense circumstellar wind shows a redder color than SHOOT14di, the shock breakout at the stellar surface of the explosion of a 25M ⊙ red supergiant star with a small explosion energy of ≤ 0.4 × 10 51 erg reproduces the multicolor light curve of SHOOT14di. This discovery shows that a high-cadence, multicolor optical transient survey at intervals of about one hour, and continuous and immediate follow-up observations, is important for studies of normal core-collapse supernovae at high redshifts.

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“…The X-ray upper limits are given by Swift-XRT and NuSTAR (Evans et al 2017), while the two detections of Chandra are indicated by the red datapoints (Troja et al 2017). For the optical band, we choose r-band to fit and the data are collected in the literature (Andreoni et al 2017;Arcavi et al 2017;Coulter et al 2017;Drout et al 2017;Kilpatrick et al 2017;Pian et al 2017;Shappee et al 2017;Smartt et al 2017). The six radio datapoints (ν = 3 GHz) are taken from Hallinan et al (2017) and could give tight constraints on models.…”

Section: Application To Gw170817/grb170817amentioning

confidence: 99%

Afterglows and Kilonovae Associated with Nearby Low-luminosity Short-duration Gamma-Ray Bursts: Application to GW170817/GRB 170817A

Xiao

Liu

Dai

et al. 2017

ApJL

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Very recently, the gravitational wave (GW) event GW170817 was discovered to be associated with the short gamma-ray burst (GRB) 170817A. Multi-wavelength follow-up observations were carried out, and X-ray, optical and radio counterparts to GW170817 were detected. The observations undoubtedly indicate that GRB170817A originates from a binary neutron star (BNS) merger. However, the GRB falls into the low-luminosity class which could have a higher statistical occurrence rate and detection probability than the normal (high-luminosity) class. This implies a possibility that GRB170817A is intrinsically powerful but we are off-axis and only observe its side emission. In this paper, we provide a timely modeling of the multi-wavelength afterglow emission from this GRB and the associated kilonova signal from the merger ejecta, under the assumption of a structured jet, a two-component jet, and an intrinsically less-energetic quasi-isotropic fireball respectively. Comparing the afterglow properties with the multi-wavelength follow-up observations, we can distinguish between these three models. Furthermore, a few model parameters (e.g., the ejecta mass and velocity) can be constrained.

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Early spectra of the gravitational wave source GW170817: Evolution of a neutron star merger

Cited by 294 publications

References 55 publications

Jet Propagation in Neutron Star Mergers and GW170817

Jet Propagation in Neutron Star Mergers and GW170817

A Rapidly Declining Transient Discovered with the Subaru/Hyper Suprime-Cam

Afterglows and Kilonovae Associated with Nearby Low-luminosity Short-duration Gamma-Ray Bursts: Application to GW170817/GRB 170817A

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