Modelling neutron star mountains in relativity

Fabian Gittins; Nils Andersson

doi:10.1093/mnras/stab2048

Modelling neutron star mountains in relativity

Fabian Gittins^*, Nils Andersson

^*Corresponding author for this work

Mathematical Sciences and STAG Research Centre, University of Southampton, Southampton SO17 1BJ, UK 0000-0002-9439-7701 [email protected]
extern
Mathematical Sciences and STAG Research Centre, University of Southampton, Southampton SO17 1BJ, UK 0000-0001-8550-3843

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

Abstract

Rapidly spinning, deformed neutron stars have long been considered potential gravitational-wave emitters. However, so far only upper limits on the size of the involved quadrupole deformations have been obtained. For this reason, it is pertinent to ask how large a mountain can be before the neutron star crust fractures. This is the question we consider in this paper, which describes how mountains can be calculated in relativistic gravity. Formally, this is a perturbative calculation that requires a fiducial force to source the mountain. Therefore, we consider three simple examples and increase their deforming amplitudes until the crust yields. We demonstrate how the derived mountains depend on the equation of state by considering a range of models obtained from chiral effective field theory. We find that the largest mountains depend sensitively on both the mechanism that sources them and the nuclear-matter equation of state.

Original language	English
Pages (from-to)	116-128
Journal	Monthly Notices of the Royal Astronomical Society
Volume	507
Issue number	1
DOIs	https://doi.org/10.1093/mnras/stab2048
Publication status	Published - 1 Oct 2021

Keywords

gravitational waves
stars: neutron

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10.1093/mnras/stab2048

http://adsabs.harvard.edu/abs/2021MNRAS.507..116G

Cite this

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title = "Modelling neutron star mountains in relativity",

abstract = "Rapidly spinning, deformed neutron stars have long been considered potential gravitational-wave emitters. However, so far only upper limits on the size of the involved quadrupole deformations have been obtained. For this reason, it is pertinent to ask how large a mountain can be before the neutron star crust fractures. This is the question we consider in this paper, which describes how mountains can be calculated in relativistic gravity. Formally, this is a perturbative calculation that requires a fiducial force to source the mountain. Therefore, we consider three simple examples and increase their deforming amplitudes until the crust yields. We demonstrate how the derived mountains depend on the equation of state by considering a range of models obtained from chiral effective field theory. We find that the largest mountains depend sensitively on both the mechanism that sources them and the nuclear-matter equation of state.",

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T1 - Modelling neutron star mountains in relativity

AU - Gittins, Fabian

AU - Andersson, Nils

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N2 - Rapidly spinning, deformed neutron stars have long been considered potential gravitational-wave emitters. However, so far only upper limits on the size of the involved quadrupole deformations have been obtained. For this reason, it is pertinent to ask how large a mountain can be before the neutron star crust fractures. This is the question we consider in this paper, which describes how mountains can be calculated in relativistic gravity. Formally, this is a perturbative calculation that requires a fiducial force to source the mountain. Therefore, we consider three simple examples and increase their deforming amplitudes until the crust yields. We demonstrate how the derived mountains depend on the equation of state by considering a range of models obtained from chiral effective field theory. We find that the largest mountains depend sensitively on both the mechanism that sources them and the nuclear-matter equation of state.

AB - Rapidly spinning, deformed neutron stars have long been considered potential gravitational-wave emitters. However, so far only upper limits on the size of the involved quadrupole deformations have been obtained. For this reason, it is pertinent to ask how large a mountain can be before the neutron star crust fractures. This is the question we consider in this paper, which describes how mountains can be calculated in relativistic gravity. Formally, this is a perturbative calculation that requires a fiducial force to source the mountain. Therefore, we consider three simple examples and increase their deforming amplitudes until the crust yields. We demonstrate how the derived mountains depend on the equation of state by considering a range of models obtained from chiral effective field theory. We find that the largest mountains depend sensitively on both the mechanism that sources them and the nuclear-matter equation of state.

KW - gravitational waves

KW - stars: neutron

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DO - 10.1093/mnras/stab2048

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VL - 507

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EP - 128

JO - Monthly Notices of the Royal Astronomical Society

JF - Monthly Notices of the Royal Astronomical Society

IS - 1

ER -

Modelling neutron star mountains in relativity

Abstract

Keywords

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