Neutrino-dominated accretion flows as the central engine of gamma-ray bursts

Liu, Tong; Gu, Wei‐Min; Zhang, Bing

doi:10.1016/j.newar.2017.07.001

Cited by 111 publications

(89 citation statements)

References 412 publications

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“…Before the central BHs or magnetars are born to power GRBs, the compact binary mergers and collapsars are also important GW sources (e.g., Cutler & Thorne 2002;Postnov & Yungelson 2014;Liu et al 2017). We here restrict ourselves only on the GWs from the GRB central engines.…”

Section: Resultsmentioning

confidence: 99%

“…Furthermore, BZ mechanism can power a GRB more easily than NDAFs, as demonstrated in Section 3.1. Those are summarized in the left panel of Figure 3 (adapted from Figure 20 in Liu et al (2017)): First, almost all SGRBs might be described in the NDAF model, with reasonable disk masses derived from the remanent of the compact objects mergers (Liu et al 2015c); Second, only about half of LGRBs might satisfy the NDAF model, while it might be necessary for the left half to introduce massive disks, extreme Kerr BHs, and high conversion efficiency for neutrino annihilation (Song et al 2016); Third, for LGRBs and ULGRBs, BZ mechanism is especially more efficient than NDAFs. Actually, the deviation between BZ mechanism and NDAFs is more significant if X-ray flares are included 1 (e.g., Liu et al 2015b;Luo et al 2013;Mu et al 2016); Fourth, the millisecond magnetar model could cover almost all types of GRBs as said before.…”

Section: Magnetarsmentioning

confidence: 99%

“…Long-duration GRBs (LGRBs) are usually regarded to be originated from the collapse of a massive star, while short-duration GRBs (SGRBs) are related to the merger events of black hole (BH)-neutron star (NS) or NS-NS binaries. In either case, the central engine of GRBs is likely to be a BH hyperaccretion system (see reviews by Liu et al 2017) or a massive millisecond magnetar (or protomagnetar, e.g., Duncan & Thompson 1992;Usov 1992;Dai & Lu 1998;Zhang & Mészáros 2001;Dai et al 2006;Metzger et al 2011).…”

Section: Introductionmentioning

confidence: 99%

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Comparison of Gravitational Waves from Central Engines of Gamma-Ray Bursts: Neutrino-dominated Accretion Flows, Blandford–Znajek Mechanisms, and Millisecond Magnetars

Liu

Lin

Song

et al. 2017

ApJ

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Neutrino-dominated accretion flow (NDAF) around a rotating stellar-mass black hole (BH) is one of the plausible candidates for the central engines of gamma-ray bursts (GRBs). Because the timevariant and anisotropic emission of neutrinos from NDAFs leads to GRB variability, NDAFs can be regarded as the sources of the strong gravitational waves (GWs). We calculate the dependences of the GW strains on both the BH spin and the accretion rate. We demonstrate that for typical GRBs with either single pulse or multiple pulses, the GWs from NDAFs might be detected at a distance of ∼ 100 kpc/∼ 1 Mpc by advanced LIGO/Einstein Telescope with a typical frequency of ∼ 10 − 100 Hz. Besides NDAFs, the other two competitive candidates for GRB central engine are Blandford-Znajek (BZ) mechanism and millisecond magnetars. We explore the GW signals from these two as well, and compare the corresponding results with NDAFs'. We find that for a certain GRB, the possible detected distance from NDAFs is about two orders of magnitude higher than that from BZ mechanism, but at least two orders of magnitude lower than that from magnetars. The typical GW frequency for BZ mechanism is the same with that of NDAFs, ∼ 10 − 100 Hz, while the typical frequency for magnetars is ∼ 2000 Hz. Therefore, the GWs released by the central engines of adjacent GRBs might be used to determine whether there is an NDAF, a BZ jet or a magnetar in GRB center.

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Section: Resultsmentioning

confidence: 99%

Section: Magnetarsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Comparison of Gravitational Waves from Central Engines of Gamma-Ray Bursts: Neutrino-dominated Accretion Flows, Blandford–Znajek Mechanisms, and Millisecond Magnetars

Liu

Lin

Song

et al. 2017

ApJ

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“…This suggests that the BZ mechanism is favored to power GRBs with long activity durations. Moreover, considering the strong outflow from the disk, the inner accretion rate is essentially always lower than the ignition accretion rate of NDAFs (for a * = 0.95 and the viscosity parameter α = 0.1, the ignition accretion rate is about 0.021 M ⊙ s −1 , where M ⊙ is the mass of Sun, see e.g., Chen & Beloborodov 2007;Zalamea & Beloborodov 2011;Liu et al 2017).…”

Section: Modelmentioning

confidence: 99%

“…For the BH case, the fall back matter triggers the BH hyperaccretion processes to power a relativistic jet breaking out from the envelope via neutrino-antineutrino annihilation mechanism liberating the gravitational energy of the BH (e.g., Ruffert et al 1997;Rosswog et al 2003), which corresponds to neutrino-dominated accretion flows (Popham et al 1999;Di Matteo et al 2002;Gu et al 2006;Liu et al 2007;Kawanaka & Mineshige 2007;Zalamea & Beloborodov 2011;Xue et al 2013;Liu et al 2016;Song et al 2016), or the Blandford-Znajek (BZ) mechanism tapping the rotational energy of the BH (e.g., Blandford & Znajek 1977;Lee et al 2000a,b;Wu et al 2013;Lei et al 2013Lei et al , 2017Liu et al 2015). For a recent review on GRB NDAFs, see Liu et al (2017). For the NS case, the spin down of a NS with a millisecond rotation period and a strong magnetic field (millisecond mag- netar) extracting the rotational energy by electromagnetic torques can produce LGRBs, even superluminous SNe (e.g., Duncan & Thompson 1992;Usov 1992;Dai & Lu 1998a,b;Kluźniak & Ruderman 1998;Zhang & Mészáros 2001;Dai et al 2006;Metzger et al 2011Metzger et al , 2015Lü et al 2015).…”

Section: Introductionmentioning

confidence: 99%

Black Hole Hyperaccretion Inflow–Outflow Model. I. Long and Ultra-long Gamma-Ray Bursts

Liu

Song

Zhang

et al. 2017

ApJ

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Long-duration gamma-ray bursts (LGRBs) and ultra-LGRBs (ULGRBs) originate from collapsars, in the center of which a newborn rotating stellar-mass black hole (BH) surrounded by a massive accretion disk may form. In the scenario of BH hyperaccretion inflow-outflow model and BlandfordZnajek (BZ) mechanism to trigger gamma-ray bursts (GRBs), the real accretion rate to power a BZ jet is far lower than the mass supply rate from the progenitor star. The characteristics of the progenitor stars can be constrained by GRB luminosity observations, and the results exceed usual expectations.LGRBs lasting from several seconds to tens of seconds in the rest frame may originate from solar-metallicity (Z ∼ 1 Z ⊙ , where Z and Z ⊙ are the metallicities of progenitor stars and the Sun), massive (M 34 M ⊙ , where M and M ⊙ are the masses of progenitor stars and the Sun) stars or some zero-metallicity (Z ∼ 0) stars. A fraction of low-metallicity (Z 10 −2 Z ⊙ ) stars, including Population III stars, can produce ULGRBs such as GRB 111209A. The fraction of LGRBs lasting less than tens of seconds in the rest frame is more than 40%, which cannot conform to the fraction of the demanded type of progenitor star. It possibly implies that the activity timescale of central engine may be much longer than the observed timescale of prompt emission phase, as indicated by X-ray late-time activities. Alternatively, LGRBs and ULGRBs may be powered by a millisecond magnetar central engine.

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Some recent results on neutrino osillations in hypercritical accretion

Uribe-Suárez

Rueda

2019

Astron Nachr

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The study of neutrino flavor oscillations in astrophysical sources has been boosted in the last two decades thanks to achievements in experimental neutrino physics and in observational astronomy. We here discuss two cases of interest in the modeling of short and long gamma-ray bursts: hypercritical, that is, highly super-Eddington spherical/disk accretion onto a neutron star/black hole.We show that in both systems, the ambient conditions of density and temperature imply the occurrence of neutrino flavor oscillations, with a relevant role of neutrino self-interactions. K E Y W O R D Sblack hole, gamma-ray bursts, neutrino flavor oscillations, neutron star 1 Astron. Nachr. / AN. 2019;340:935-944.www.an-journal.org

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Neutrino-dominated accretion flows as the central engine of gamma-ray bursts

Cited by 111 publications

References 412 publications

Comparison of Gravitational Waves from Central Engines of Gamma-Ray Bursts: Neutrino-dominated Accretion Flows, Blandford–Znajek Mechanisms, and Millisecond Magnetars

Comparison of Gravitational Waves from Central Engines of Gamma-Ray Bursts: Neutrino-dominated Accretion Flows, Blandford–Znajek Mechanisms, and Millisecond Magnetars

Black Hole Hyperaccretion Inflow–Outflow Model. I. Long and Ultra-long Gamma-Ray Bursts

Some recent results on neutrino osillations in hypercritical accretion

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