Long-duration Gamma-Ray Burst and Associated Kilonova Emission from Fast-spinning Black Hole–Neutron Star Mergers

Zhu, Jin-Ping; Wang, X.; Sun, Hui; Yang, Yuan-Pei; Li, Zhuo; Hu, Rui-Chong; Qin, Ying; Wu, Shichao

doi:10.3847/2041-8213/ac85ad

Cited by 27 publications

(21 citation statements)

References 153 publications

(208 reference statements)

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“…The possibility to detect a gamma-ray burst (GRB) in connection with a BH+NS merger depends crucially on the spin rate of the BH, and thus on which compact object formed first (Fragione et al 2021;Román-Garza et al 2021;Hu et al 2022;Zhu et al 2022). Since the BH formed first in our Systems A, B, and C, it is anticipated to be relatively slowly spinning and therefore the subsequent BH+NS merger event would most likely prevent tidal disruption from occurring, and therefore not produce a GRB source.…”

Section: Connection To Final Fate Of Ss 433 and Grbsmentioning

confidence: 99%

Simulations of the Progenitors of Black Hole–Neutron Star Gravitational Wave Sources

Jiang

Chen

Tauris

et al. 2023

ApJ

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Recent discoveries of gravitational wave (GW) events most likely originating from black hole (BH) + neutron star (NS) mergers reveal the existence of BH+NS binaries. The formation of BH+NS binaries and their merger rates through isolated binary evolution have been investigated extensively with population synthesis simulations. A detailed stellar evolution modeling of the formation of this population, however, is missing from the literature. In this work, we create the first complete 1D model of more than 30 BH+NS progenitor systems, which are calculated self-consistently until collapse of the iron core with infall velocity exceeding 1000 km s−1. Focusing on the progenitors of BH–NS GW sources, we apply the MESA code starting from a post-common-envelope binary with short orbital period (<1 day) consisting of a BH and a zero-age main-sequence helium star that experiences stable mass transfer. The (ultra)stripped supernova explosion is subsequently modeled using a semianalytic method to reveal final remnant masses and momentum kicks. Three example systems (A, B, and C) eventually evolve into BH+NS binaries with component masses of (M BH, M NS) = (8.80, 1.53), (8.92, 1.45), and (5.71, 1.34) M ⊙, respectively. These NS masses could be significantly larger depending on the exact mass cut during the supernova explosion. These BH+NS systems are likely to merge and produce GW events within a Hubble time. System C is a potential progenitor of a GW200115-like event, while Systems A and B are possible candidates for a GW200105-like event and may represent the final destiny of the X-ray binary SS 433.

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Section: Connection To Final Fate Of Ss 433 and Grbsmentioning

confidence: 99%

Simulations of the Progenitors of Black Hole–Neutron Star Gravitational Wave Sources

Jiang

Chen

Tauris

et al. 2023

ApJ

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“…Until recently, a kilonova-like emission with similar luminosity, duration, and color to AT 2017gfo, associated with GRB 211211A and located in a nearby host galaxy SDSS J140910.47 + 275320.8 with a distance ∼350 Mpc, was reported and analyzed by Rastinejad et al (2022), Yang et al (2022), Mei et al (2022), Troja et al (2022), Gompertz et al (2023), and Xiao et al (2022). From the evidence of the host galaxy properties including the offset, the features of the kilonova-like emission, the modeling for the light curves of afterglows and kilonova-like emission, and the exponential decline phase and spectral features in GRB 211211A, most authors suggested or directly considered this association to arise from a compact star merger (Gao et al 2022;Gompertz et al 2023;Mei et al 2022;Rastinejad et al 2022;Troja et al 2022;Xiao et al 2022;Yang et al 2022;Zhang et al 2022;Zhu et al 2022;Chang et al 2023;Kunert et al 2023), while a few authors mainly discussed the explanation or possibility in a collapsar origin (Waxman et al 2022;Barnes & Metzger 2023). The final central engine either a black hole (BH) or magnetar is also under debate.…”

Section: Introductionmentioning

confidence: 99%

GRB 211211A: A Neutron Star–White Dwarf Merger?

Zhong

Dai

2023

ApJL

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The gamma-ray burst GRB 211211A and its associated kilonova-like emission were reported recently. A significant difference between this association event and GRB 170817A/AT 2017gfo is that GRB 211211A has a very long duration. In this Letter, we show that this association event may arise from a neutron star–white dwarf (NS–WD) merger if the central engine leaves a magnetar behind. Within the NS–WD merger, the main burst of GRB 211211A could be produced by magnetic bubble eruptions from toroidal magnetic field amplification of the premerger NS. This toroidal field amplification can be induced by the runaway accretion from the WD debris disk if the disk is in low initial entropy and efficient wind, while the extended emission of GRB 211211A is likely involved with magnetic propelling. The observed energetics and duration of the prompt emission of GRB 211211A can be fulfilled in comparison with those of accretion in a hydrodynamical thermonuclear simulation, as long as the WD has a mass ≳1M ⊙. Moreover, if the X-ray plateau in GRB afterglows is due to the magnetar spin-down radiation, GRB optical afterglows and kilonova-like emission can be jointly well modeled combining the standard forward shock with the radioactive decay power of 56Ni adding a rotational power input from the postmerger magnetar.

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“…To date, except for AT2017gfo, other kilonova candidates were all detected in superposition with decaying sGRB afterglows (e.g., Berger et al 2013;Fan et al 2013;Tanvir et al 2013;Gao et al 2015Gao et al , 2017Jin et al 2015Jin et al , 2016Jin et al , 2020Yang et al 2015;Gompertz et al 2018;Ascenzi et al 2019;Rossi et al 2020;Fong et al 2021;Ma et al 2021;Wu et al 2021;Yuan et al 2021). Interestingly, a bright kilonova candidate was recently found to be associated with a longduration GRB 211211A (e.g., Rastinejad et al 2022;Troja et al 2022;Yang et al 2022b;Zhu et al 2022a). One possible reason why almost all kilonova candidates were detected in GRB afterglows is that most BNS and NSBH mergers are far away from us.…”

Section: Introductionmentioning

confidence: 99%

Kilonovae and Optical Afterglows from Binary Neutron Star Mergers. II. Optimal Search Strategy for Serendipitous Observations and Target-of-opportunity Observations of Gravitational Wave Triggers

Zhu

Yang

et al. 2023

ApJ

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In the second work of this series, we explore the optimal search strategy for serendipitous and gravitational-wave-triggered target-of-opportunity (ToO) observations of kilonovae and optical short-duration gamma-ray burst (sGRB) afterglows from binary neutron star (BNS) mergers, assuming that cosmological kilonovae are AT2017gfo-like (but with viewing-angle dependence) and that the properties of afterglows are consistent with those of cosmological sGRB afterglows. A one-day cadence serendipitous search strategy with an exposure time of ∼30 s can always achieve an optimal search strategy of kilonovae and afterglows for various survey projects. We show that the optimal detection rates of the kilonovae (afterglows) are ∼0.3/0.6/1/20 yr−1 (∼50/60/100/800 yr−1) for Zwicky the Transient Facility (ZTF)/Multi-channel Photometric Survey Telescope (Mephisto)/Wide Field Survey Telescope (WFST)/Large Synoptic Survey Telescope (LSST), respectively. A better search strategy for SiTian than the current design is to increase the exposure time. In principle, a fully built SiTian can detect ∼7(2000) yr−1 kilonovae (afterglows). Population properties of electromagnetic (EM) signals detected by serendipitous observations are studied in detail. For ToO observations, we predict that one can detect ∼11 yr−1 BNS gravitational wave (GW) events during the fourth observing run (O4) by considering an exact duty cycle of the third observing run. The median GW sky localization area is expected to be ∼10 deg2 for detectable BNS GW events. For O4, we predict that ZTF/Mephisto/WFST/LSST can detect ∼5/4/3/3 kilonovae (∼1/1/1/1 afterglows) per year, respectively. The GW detection rates, GW population properties, GW sky localizations, and optimistic ToO detection rates of detectable EM counterparts for BNS GW events at the Advanced Plus, LIGO Voyager, and ET&CE eras are detailedly simulated in this paper.

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Long-duration Gamma-Ray Burst and Associated Kilonova Emission from Fast-spinning Black Hole–Neutron Star Mergers

Cited by 27 publications

References 153 publications

Simulations of the Progenitors of Black Hole–Neutron Star Gravitational Wave Sources

Simulations of the Progenitors of Black Hole–Neutron Star Gravitational Wave Sources

GRB 211211A: A Neutron Star–White Dwarf Merger?

Kilonovae and Optical Afterglows from Binary Neutron Star Mergers. II. Optimal Search Strategy for Serendipitous Observations and Target-of-opportunity Observations of Gravitational Wave Triggers

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