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On the diversity of magnetar-driven kilonovae

On the diversity of magnetar-driven kilonovae
On the diversity of magnetar-driven kilonovae
A non-negligible fraction of binary neutron star mergers are expected to form long-lived neutron star remnants, dramatically altering the multimessenger signatures of a merger. Here, we extend existing models for magnetar-driven kilonovae and explore the diversity of kilonovae and kilonova afterglows. Focusing on the role of the (uncertain) magnetic field strength, we study the resulting electromagnetic signatures as a function of the external dipolar and internal toroidal fields. These two parameters govern, respectively, the competition between magnetic-dipole spin-down and gravitational-wave spin-down (due to magnetic-field deformation) of the rapidly rotating remnant. We find that even in the parameter space where gravitational-wave emission is dominant, a kilonova with a magnetar central engine will be significantly brighter than one without an engine, as this parameter space is where more of the spin-down luminosity is thermalized. In contrast, a system with minimal gravitational-wave emission will produce a kilonova that may be difficult to distinguish from ordinary kilonovae unless early epoch observations are available. However, as the bulk of the energy in this parameter space goes into accelerating the ejecta, such a system will produce a brighter kilonova afterglow that will peak in shorter times. To effectively hide the presence of the magnetar from the kilonova and kilonova afterglow, the rotational energy inputted into the ejecta must be ≲10−3to 10−2Erot. We discuss the different diagnostics available to identify magnetar-driven kilonovae in serendipitous observations and draw parallels to other potential magnetar-driven explosions, such as superluminous supernovae and broad-line supernovae Ic.
1365-2966
4949-4962
Sarin, Nikhil
bfde4e6e-0c6d-4f0f-898e-7ec34b4602ef
Omand, Conor M.B.
a91156be-99f7-407d-a279-a355a330dfab
Margalit, Ben
b0bfc3e8-ff5f-4a40-83dc-0e7e057d7396
Jones, David I
b8f3e32c-d537-445a-a1e4-7436f472e160
Sarin, Nikhil
bfde4e6e-0c6d-4f0f-898e-7ec34b4602ef
Omand, Conor M.B.
a91156be-99f7-407d-a279-a355a330dfab
Margalit, Ben
b0bfc3e8-ff5f-4a40-83dc-0e7e057d7396
Jones, David I
b8f3e32c-d537-445a-a1e4-7436f472e160

Sarin, Nikhil, Omand, Conor M.B., Margalit, Ben and Jones, David I (2022) On the diversity of magnetar-driven kilonovae. Monthly Notices Of The Royal Astronomical Society, 516 (4), 4949-4962. (doi:10.1093/mnras/stac2609).

Record type: Article

Abstract

A non-negligible fraction of binary neutron star mergers are expected to form long-lived neutron star remnants, dramatically altering the multimessenger signatures of a merger. Here, we extend existing models for magnetar-driven kilonovae and explore the diversity of kilonovae and kilonova afterglows. Focusing on the role of the (uncertain) magnetic field strength, we study the resulting electromagnetic signatures as a function of the external dipolar and internal toroidal fields. These two parameters govern, respectively, the competition between magnetic-dipole spin-down and gravitational-wave spin-down (due to magnetic-field deformation) of the rapidly rotating remnant. We find that even in the parameter space where gravitational-wave emission is dominant, a kilonova with a magnetar central engine will be significantly brighter than one without an engine, as this parameter space is where more of the spin-down luminosity is thermalized. In contrast, a system with minimal gravitational-wave emission will produce a kilonova that may be difficult to distinguish from ordinary kilonovae unless early epoch observations are available. However, as the bulk of the energy in this parameter space goes into accelerating the ejecta, such a system will produce a brighter kilonova afterglow that will peak in shorter times. To effectively hide the presence of the magnetar from the kilonova and kilonova afterglow, the rotational energy inputted into the ejecta must be ≲10−3to 10−2Erot. We discuss the different diagnostics available to identify magnetar-driven kilonovae in serendipitous observations and draw parallels to other potential magnetar-driven explosions, such as superluminous supernovae and broad-line supernovae Ic.

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On the diversity of magnetar-driven kilonovae - Accepted Manuscript
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Accepted/In Press date: 9 September 2022
e-pub ahead of print date: 15 September 2022
Published date: 24 September 2022

Identifiers

Local EPrints ID: 471565
URI: http://eprints.soton.ac.uk/id/eprint/471565
DOI: doi:10.1093/mnras/stac2609
ISSN: 1365-2966
PURE UUID: 21e96e58-80b2-454b-ba83-4416bd189dfe
ORCID for David I Jones: ORCID iD orcid.org/0000-0002-0117-7567

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Date deposited: 11 Nov 2022 17:36
Last modified: 17 Mar 2024 02:48

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Contributors

Author: Nikhil Sarin
Author: Conor M.B. Omand
Author: Ben Margalit
Author: David I Jones ORCID iD

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