PRODUCTION OF ALL THE
                    <i>r</i>
                    -PROCESS NUCLIDES IN THE DYNAMICAL EJECTA OF NEUTRON STAR MERGERS

Wanajo, Shinya; Sekiguchi, Y.; Nishimura, Nobuya; Kiuchi, Kenta; Kyutoku, Koutarou; Shibata, Masaru

doi:10.1088/2041-8205/789/2/l39

Cited by 615 publications

(902 citation statements)

References 46 publications

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“…Most importantly, the total ejected amount of r-material made of heavy r-nuclei is dramatically reduced. Our study therefore confirms the results of [7] and implies that a proper treatment of the neutrino physics is essential for making quantitative predictions of the elemental yields and especially of the total mass of r-process material that is thrown out by the dynamical merger ejecta.…”

Section: Nucleosynthesis Relevant Outflow Componentssupporting

confidence: 86%

“…[5]). However, it was recently realized that the nucleosynthesis signature of NS mergers is more complex when taking into account ν-interactions in relativistic NS-NS merger simulations and when the ejecta No e ± -capture, no !-interactions for " < " from the merger remnant are consistently included [1,[6][7][8][9][10]. In contrast to NS-BH mergers, in NS-NS mergers the large pressure gradient that is generated by the collision shock building up between both NSs causes a sizable amount of material to become unbound in addition to possible tidal-tail ejecta from the disrupted NS(s).…”

Section: Nucleosynthesis Relevant Outflow Componentsmentioning

confidence: 99%

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Impact of Neutrino Interactions on Outflows of Neutron-Star Mergers

Just

Goriely²,

Bauswein³

et al. 2017

Proceedings of the 14th International Symposium on Nuclei in the Cosmos (NIC2016)

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Despite significant progress in the recent years a robust identification of the main astrophysical source or sources of the rapid-neutron-capture (r-) process is still lacking. Neutrino-driven winds in ordinary core-collapse supernovae seem to be ruled out as main r-process sources because of their insufficiently low neutron densities and entropies. Magnetorotationally driven supernovae might provide r-process conditions, but only if the magnetic field is strong enough (or builds up quickly enough) to launch the explosion on a sufficiently short timescale; if or for how many progenitors this condition is met is largely unclear at the moment. Neutron-star (NS) mergers, i.e. mergers of two NSs or of a NS with a black hole (BH), could robustly produce r-process viable outflows in most events and by means of multiple ejecta components. Using a combination of neutrino-hydrodynamics simulations and post-processing nucleosynthesis calculations we investigated the different ejecta components and their r-process yields. Apart from the massive, nucleosynthesis relevant outflows also ultrarelativistic jets could emerge from the remnant of a NS merger. These jets are widely believed to explain the still mysterious origin of short gamma-ray bursts (sGRBs), but the main agent launching the jet remains disputed. We outline a recent study that explores one popular scenario in which the jet is being driven entirely due to heating by pair-annihilation of neutrinos.

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Section: Nucleosynthesis Relevant Outflow Componentssupporting

confidence: 86%

Section: Nucleosynthesis Relevant Outflow Componentsmentioning

confidence: 99%

Impact of Neutrino Interactions on Outflows of Neutron-Star Mergers

Just

Goriely²,

Bauswein³

et al. 2017

Proceedings of the 14th International Symposium on Nuclei in the Cosmos (NIC2016)

View full text Add to dashboard Cite

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“…Alternative ways to cure the problems of the 3rd r-process peak discussed above, come from full general relativistic modeling of the merger event. This leads to deeper gravitational potentials, higher temperatures (including neutrino energies), electron-positron pairs, which -via positron captures and neutrino interaction with nuclei/nucleons -increase Y e to values of the order 0.15, comparable to those mentioned above in MHD-supernova (magnetar) jets [18,78], where the 3rd peak shift did not occur.…”

Section: Neutron Star Mergersmentioning

confidence: 66%

“…Optical and near-infrared observations of such an event, accompanying the short-duration GRB130603B have been reported [71] (see also [4]). After the first detailed nucleosynthesis predictions (following ideas of [33]) of such an event [13], many more and more sophisticated investigations have been undertaken, involving quite a number of authors [5,12,16,17,27,32,39,42,51,56,61,78] as well as the black hole accretion disk system after the formation of a central black hole [27,70,78,82].…”

Section: Neutron Star Mergersmentioning

confidence: 99%

“…This causes a very strong r-process with fission cycling. The utilized mass model, beta-decay half-lives, fission barriers, and fission yield prescriptions [12,18,29,38,42,55,65,78] have a strong effect on the final abundance distribution. While during the r-process (when reactions are still in n, γ − γ, n equilibrium) the 2nd and 3rd r-process peak are exactly at the right position.…”

Section: Neutron Star Mergersmentioning

confidence: 99%

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Nucleosynthesis in Supernovae, Hypernovae/Gamma-ray Bursts and Compact Binary Mergers

Thielemann¹

2017

Proceedings of the 14th International Symposium on Nuclei in the Cosmos (NIC2016)

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We present the status and open problems of the astrophysical sites responsible for the nucleosynthesis of Fe-group and heavier elements (with the exception of the s-process). This involves type Ia supernovae with the requirement to have a low Y e -component (for the explanation of 55 Mn), the role of the core collapse supenova explosion mechanism in the composition of the Fe-group (and heavier?) ejecta, the transition between neutron star and black hole remnants as the result of the collapse of massive stars, and the relation of the latter with supernova and/or gamma-ray bursts / hypernovae. In addition, the role of compact binary mergers is discussed, especially with respect to forming the heaviest r-process elements in galactic eveolution.

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Heavy Elements and Electromagnetic Transients from Neutron Star Mergers

Rosswog

Korobkin

2022

Annalen der Physik

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Compact binary mergers involving neutron stars can eject a fraction of their mass to space. Being extremely neutron rich, this material undergoes rapid neutron capture nucleosynthesis, and the resulting radioactivity powers fast, short‐lived electromagnetic transients known as kilonova or macronova. Such transients are exciting probes of the most extreme physical conditions and their observation signals the enrichment of the Universe with heavy elements. Here the current understanding of the mass ejection mechanisms, the properties of the ejecta, and the resulting radioactive transients are reviewed. The first well‐observed event in the aftermath of GW170817 delivered a wealth of insights, but much of today's picture of such events is still based on a patchwork of theoretical studies. Apart from summarizing the current understanding, questions where no consensus has been reached yet are also pointed out, and possible directions for the future research are sketched. In an appendix, a publicly available heating rate library based on the WinNet nuclear reaction network is described, and a simple fit formula to alleviate the implementation in hydrodynamic simulations is provided.

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PRODUCTION OF ALL THE r -PROCESS NUCLIDES IN THE DYNAMICAL EJECTA OF NEUTRON STAR MERGERS

Cited by 615 publications

References 46 publications

Impact of Neutrino Interactions on Outflows of Neutron-Star Mergers

Impact of Neutrino Interactions on Outflows of Neutron-Star Mergers

Nucleosynthesis in Supernovae, Hypernovae/Gamma-ray Bursts and Compact Binary Mergers

Heavy Elements and Electromagnetic Transients from Neutron Star Mergers

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