Kilonovae

Metzger, Brian

doi:10.1007/s41114-019-0024-0

Cited by 436 publications

(396 citation statements)

References 417 publications

(597 reference statements)

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“…From ultraviolet through infrared, observations of the GW170817 remnant (labeled the astronomical transient AT2017gfo) strikingly confirmed the behavior of a radioactively-powered kilonova (see, e.g., 6 and references therein). A spectrum initially peaked in ultraviolet progressed through blue to red over about three days and then to infrared, 88-90 supporting models whose ejecta had a range of neutron fractions.…”

Section: The Gw170817 Kilonovamentioning

confidence: 69%

“…5,58,59 To reproduce the observed abundance of lighter r-process nuclides, the ejecta must also include a less neutron rich component, with the ratio proton/baryon 0.25, and that is seen in simulations of mergers with M < M thres , mergers in which a massive neutron star briefly supports itself against collapse. 6,[59][60][61][62] In merger simulations, the first ejecta are neutron rich. If a high-mass neutron star is formed, the e ± production and subsequent weak interactions that lead to loss of most of the merger energy in neutrinos also deplete the number of neutrons: The higher density of neutrons means a higher rate of n → p than p → n conversions, from positron and neutrino capture.…”

Section: R-process Nucleosynthesismentioning

confidence: 99%

“…The brightness and timescale are key signatures of the formation of r-process material whose radioactive decay powers the kilonova, and we give brief estimates here. Li and Paczynski 80 first suggested an observable optical glow from merger ejecta in 1998; see Metzger 6 for a review and references.…”

Section: Kilonovaementioning

confidence: 99%

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Gravitational-wave astrophysics from neutron star inspiral and coalescence

Friedman

2018

Int. J. Mod. Phys. D

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The first inspiral of two neutron stars observed in gravitational waves was remarkably close, allowing the kind of simultaneous gravitational wave and electromagnetic observation that had not been expected for several years. Their merger, followed by a gamma-ray burst and a kilonova, was observed across the spectral bands of electromagnetic telescopes. These GW and electromagnetic observations have led to dramatic advances in understanding short gamma-ray bursts; determining the origin of the heaviest elements; and determining the maximum mass of neutron stars. From the imprint of tides on the gravitational waveforms and from observations of X-ray binaries, one can extract the radius and deformability of inspiraling neutron stars. Together, the radius, maximum mass, and causality constrain the neutron-star equation of state, and future constraints can come from observations of post-merger oscillations. We selectively review these results, filling in some of the physics with derivations and estimates.

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Section: The Gw170817 Kilonovamentioning

confidence: 69%

Section: R-process Nucleosynthesismentioning

confidence: 99%

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Gravitational-wave astrophysics from neutron star inspiral and coalescence

Friedman

2018

Int. J. Mod. Phys. D

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“…The above results also limit a possible electromagnetic (EM) counterpart to the GW signal from its environment (Kocsis & Loeb 2008;Li et al 2012), unrelated to the possible EM emission by the source itself (Loeb 2016;D'Orazio & Loeb 2018;Metzger 2019). The dissipation of a fraction ǫ diss of the GW energy, E GW , in a baryonic system surrounding the GW source, would lead to an EM counterpart with a luminosity,…”

Section: Electromagnetic Counterpartsmentioning

confidence: 84%

Upper Limit on the Dissipation of Gravitational Waves in Gravitationally Bound Systems

Loeb

2020

ApJL

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It is shown that a gravitationally bound system with a one-dimensional velocity dispersion σ can at most dissipate a fraction ∼ 36(σ/c) 3 of the gravitational wave energy propagating through it, even if their dynamical time is shorter than the wave period. The limit is saturated for low frequency waves propagating through a system of particles with a mean-free-path equal to the size of the system, such as hot protons in galaxy clusters, strongly-interacting dark matter particles in halos, or massive black holes in clusters. For such systems with random motions and no resonances, the dissipated fraction, 10 −6 , does not degrade the use of gravitational waves as cosmological probes. At high wave frequencies, the dissipated fraction is additionally suppressed by the square of the ratio between the collision frequency and the wave frequency. The electromagnetic counterparts that result from the dissipation are too faint to be detectable at cosmological distances.

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“…Concerning the second point, the amount and composition of the ejecta depend on how and when dur-ing the merger the material has become unbound (for a review, see Metzger 2019). The most neutron-rich component known as "dynamical ejecta" gets unbound by dynamical tide and attains ideal conditions for robust r-process nucleosynthesis (Freiburghaus et al 1999;Korobkin et al 2012;Bauswein et al 2013).…”

Section: The R-process Yields From Kilonovaementioning

confidence: 99%

Gamma-Rays from Kilonovae and the Cosmic Gamma-Ray Background

Ruiz‐Lapuente

Korobkin

2020

ApJ

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The recent detection of the gravitational wave event GW170817, produced by the coalescence of two neutron stars, and of its optical-infrared counterpart, powered by the radioactive decay of rprocess elements, has opened a new window to gamma-ray astronomy: the direct detection of photons coming from such decays. Here we calculate the contribution of kilonovae to the diffuse gamma-ray background in the MeV range, using recent results on the spectra of the gamma-rays emitted in individual events, and we compare it with that from other sources. We find that the contribution from kilonovae is not dominant in such energy range, but within current uncertainties, its addition to other sources might help to fit the observational data.

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Kilonovae

Cited by 436 publications

References 417 publications

Gravitational-wave astrophysics from neutron star inspiral and coalescence

Gravitational-wave astrophysics from neutron star inspiral and coalescence

Upper Limit on the Dissipation of Gravitational Waves in Gravitationally Bound Systems

Gamma-Rays from Kilonovae and the Cosmic Gamma-Ray Background

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