Bound Debris Expulsion from Neutron Star Merger Remnants

Yossef Zenati; Julian H. Krolik; Leonardo R. Werneck; Ariadna Murguia-Berthier; Zachariah B. Etienne; Scott C. Noble; Tsvi Piran

doi:10.3847/1538-4357/acf714

Bound Debris Expulsion from Neutron Star Merger Remnants

Yossef Zenati, Julian H. Krolik, Leonardo R. Werneck, Ariadna Murguia-Berthier, Zachariah B. Etienne, Scott C. Noble, Tsvi Piran

Racah Institute of Physics

The Hebrew University of Jerusalem

Research output: Contribution to journal › Article › peer-review

Abstract

Many studies have found that neutron star mergers leave a fraction of the stars’ mass in bound orbits surrounding the resulting massive neutron star or black hole. This mass is a site of r-process nucleosynthesis and can generate a wind that contributes to a kilonova. However, comparatively little is known about the dynamics determining its mass or initial structure. Here we begin to investigate these questions, starting with the origin of the disk mass. Using tracer particle as well as discretized fluid data from numerical simulations, we identify where in the neutron stars the debris came from, the paths it takes in order to escape from the neutron stars’ interiors, and the times and locations at which its orbital properties diverge from those of neighboring fluid elements that end up remaining in the merged neutron star.

Original language	English
Article number	161
Journal	Astrophysical Journal
Volume	2
Issue number	161
DOIs	https://doi.org/10.3847/1538-4357/acf714
State	Published - 1 Dec 2023

All Science Journal Classification (ASJC) codes

Astronomy and Astrophysics
Space and Planetary Science

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10.3847/1538-4357/acf714

Cite this

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title = "Bound Debris Expulsion from Neutron Star Merger Remnants",

abstract = "Many studies have found that neutron star mergers leave a fraction of the stars{\textquoteright} mass in bound orbits surrounding the resulting massive neutron star or black hole. This mass is a site of r-process nucleosynthesis and can generate a wind that contributes to a kilonova. However, comparatively little is known about the dynamics determining its mass or initial structure. Here we begin to investigate these questions, starting with the origin of the disk mass. Using tracer particle as well as discretized fluid data from numerical simulations, we identify where in the neutron stars the debris came from, the paths it takes in order to escape from the neutron stars{\textquoteright} interiors, and the times and locations at which its orbital properties diverge from those of neighboring fluid elements that end up remaining in the merged neutron star.",

author = "Yossef Zenati and Krolik, \{Julian H.\} and Werneck, \{Leonardo R.\} and Ariadna Murguia-Berthier and Etienne, \{Zachariah B.\} and Noble, \{Scott C.\} and Tsvi Piran",

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doi = "10.3847/1538-4357/acf714",

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T1 - Bound Debris Expulsion from Neutron Star Merger Remnants

AU - Zenati, Yossef

AU - Krolik, Julian H.

AU - Werneck, Leonardo R.

AU - Murguia-Berthier, Ariadna

AU - Etienne, Zachariah B.

AU - Noble, Scott C.

AU - Piran, Tsvi

PY - 2023/12/1

Y1 - 2023/12/1

N2 - Many studies have found that neutron star mergers leave a fraction of the stars’ mass in bound orbits surrounding the resulting massive neutron star or black hole. This mass is a site of r-process nucleosynthesis and can generate a wind that contributes to a kilonova. However, comparatively little is known about the dynamics determining its mass or initial structure. Here we begin to investigate these questions, starting with the origin of the disk mass. Using tracer particle as well as discretized fluid data from numerical simulations, we identify where in the neutron stars the debris came from, the paths it takes in order to escape from the neutron stars’ interiors, and the times and locations at which its orbital properties diverge from those of neighboring fluid elements that end up remaining in the merged neutron star.

AB - Many studies have found that neutron star mergers leave a fraction of the stars’ mass in bound orbits surrounding the resulting massive neutron star or black hole. This mass is a site of r-process nucleosynthesis and can generate a wind that contributes to a kilonova. However, comparatively little is known about the dynamics determining its mass or initial structure. Here we begin to investigate these questions, starting with the origin of the disk mass. Using tracer particle as well as discretized fluid data from numerical simulations, we identify where in the neutron stars the debris came from, the paths it takes in order to escape from the neutron stars’ interiors, and the times and locations at which its orbital properties diverge from those of neighboring fluid elements that end up remaining in the merged neutron star.

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Bound Debris Expulsion from Neutron Star Merger Remnants

Abstract

All Science Journal Classification (ASJC) codes

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