The gravitational afterglow of boson stars

Eugene Lim; Robin Croft; Ulrich Sperhake; Thomas Helfer; Bo-Xuan Ge; Katy Clough; Miren Radia

doi:10.1088/1361-6382/acace4

The gravitational afterglow of boson stars

Eugene Lim, Robin Croft, Ulrich Sperhake, Thomas Helfer, Bo-Xuan Ge, Katy Clough, Miren Radia

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Abstract

In this work we study the long-lived post-merger gravitational wave signature of a boson-star binary coalescence. We use full numerical relativity to simulate the post-merger and track the gravitational afterglow over an extended period of time. We implement recent innovations for the binary initial data, which significantly reduce spurious initial excitations of the scalar field profiles, as well as a measure for the angular momentum that allows us to track the total momentum of the spatial volume, including the curvature contribution. Crucially, we find the afterglow to last much longer than the spin-down timescale. This prolonged gravitational wave afterglow provides a characteristic signal that may distinguish it from other astrophysical sources.

Original language	English
Journal	Classical and Quantum Gravity
DOIs	https://doi.org/10.1088/1361-6382/acace4
Publication status	Published - 12 Jul 2022

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10.1088/1361-6382/acace4Licence: CC BY

Croft_2023_Class._Quantum_Grav._40_065001Accepted author manuscript, 1.62 MBLicence: CC BY

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abstract = "In this work we study the long-lived post-merger gravitational wave signature of a boson-star binary coalescence. We use full numerical relativity to simulate the post-merger and track the gravitational afterglow over an extended period of time. We implement recent innovations for the binary initial data, which significantly reduce spurious initial excitations of the scalar field profiles, as well as a measure for the angular momentum that allows us to track the total momentum of the spatial volume, including the curvature contribution. Crucially, we find the afterglow to last much longer than the spin-down timescale. This prolonged gravitational wave afterglow provides a characteristic signal that may distinguish it from other astrophysical sources.",

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T1 - The gravitational afterglow of boson stars

AU - Lim, Eugene

AU - Croft, Robin

AU - Sperhake, Ulrich

AU - Helfer, Thomas

AU - Ge, Bo-Xuan

AU - Clough, Katy

AU - Radia, Miren

PY - 2022/7/12

Y1 - 2022/7/12

N2 - In this work we study the long-lived post-merger gravitational wave signature of a boson-star binary coalescence. We use full numerical relativity to simulate the post-merger and track the gravitational afterglow over an extended period of time. We implement recent innovations for the binary initial data, which significantly reduce spurious initial excitations of the scalar field profiles, as well as a measure for the angular momentum that allows us to track the total momentum of the spatial volume, including the curvature contribution. Crucially, we find the afterglow to last much longer than the spin-down timescale. This prolonged gravitational wave afterglow provides a characteristic signal that may distinguish it from other astrophysical sources.

AB - In this work we study the long-lived post-merger gravitational wave signature of a boson-star binary coalescence. We use full numerical relativity to simulate the post-merger and track the gravitational afterglow over an extended period of time. We implement recent innovations for the binary initial data, which significantly reduce spurious initial excitations of the scalar field profiles, as well as a measure for the angular momentum that allows us to track the total momentum of the spatial volume, including the curvature contribution. Crucially, we find the afterglow to last much longer than the spin-down timescale. This prolonged gravitational wave afterglow provides a characteristic signal that may distinguish it from other astrophysical sources.

U2 - 10.1088/1361-6382/acace4

DO - 10.1088/1361-6382/acace4

M3 - Article

SN - 0264-9381

JO - Classical and Quantum Gravity

JF - Classical and Quantum Gravity

ER -

The gravitational afterglow of boson stars

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