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Fully constrained, high-resolution shock-capturing, formulation of the Einstein-fluid equations in 2+1 dimensions

Fully constrained, high-resolution shock-capturing, formulation of the Einstein-fluid equations in 2+1 dimensions
Fully constrained, high-resolution shock-capturing, formulation of the Einstein-fluid equations in 2+1 dimensions

Four components of the axisymmetric Einstein equations in 2+1 dimensions with negative cosmological constant can be written as aM=... and aJ=..., where the dots stand for stress-energy terms, and M and J are scalars. In vacuum, they reduce to the constant mass and angular momentum parameters of the BTZ solution of the same name. The integrability conditions for the Einstein equations give rise to two conserved stress-energy currents aj(M)a=0 and aj(J)a=0. The angular momentum current is just the Noether current due to axisymmetry, but the mass current is unexpected in the presence of rotation. The conserved quantity M exists in all dimensions in spherical symmetry, known as the Misner-Sharp, Hawking or Kodama mass, but in 2+1 dimensions M exists also in axisymmetry, even with rotation. We use M and J to give a fully constrained formulation of the axisymmetric Einstein equations in 2+1 dimensions, where the Einstein equations are solved by explicit integration from the center along time slices. We use the two conserved matter currents in the construction of a high-resolution shock-capturing formulation of the Einstein-perfect fluid system, in which M and J momentum are then exactly conserved by construction. We demonstrate convergence of the code in the test cases of generic dispersion and collapse and stable and unstable rotating stars.

2470-0010
Gundlach, Carsten
586f1eb5-3185-4b2b-8656-c29c436040fc
Bourg, Patrick
7243e5d7-edd5-4066-89d3-f8357dbde8f8
Davey, Alex
f234b9bc-276d-4fbc-9984-f90697489208
Gundlach, Carsten
586f1eb5-3185-4b2b-8656-c29c436040fc
Bourg, Patrick
7243e5d7-edd5-4066-89d3-f8357dbde8f8
Davey, Alex
f234b9bc-276d-4fbc-9984-f90697489208

Gundlach, Carsten, Bourg, Patrick and Davey, Alex (2021) Fully constrained, high-resolution shock-capturing, formulation of the Einstein-fluid equations in 2+1 dimensions. Physical Review D, 104 (2), [024061]. (doi:10.1103/PhysRevD.104.024061).

Record type: Article

Abstract

Four components of the axisymmetric Einstein equations in 2+1 dimensions with negative cosmological constant can be written as aM=... and aJ=..., where the dots stand for stress-energy terms, and M and J are scalars. In vacuum, they reduce to the constant mass and angular momentum parameters of the BTZ solution of the same name. The integrability conditions for the Einstein equations give rise to two conserved stress-energy currents aj(M)a=0 and aj(J)a=0. The angular momentum current is just the Noether current due to axisymmetry, but the mass current is unexpected in the presence of rotation. The conserved quantity M exists in all dimensions in spherical symmetry, known as the Misner-Sharp, Hawking or Kodama mass, but in 2+1 dimensions M exists also in axisymmetry, even with rotation. We use M and J to give a fully constrained formulation of the axisymmetric Einstein equations in 2+1 dimensions, where the Einstein equations are solved by explicit integration from the center along time slices. We use the two conserved matter currents in the construction of a high-resolution shock-capturing formulation of the Einstein-perfect fluid system, in which M and J momentum are then exactly conserved by construction. We demonstrate convergence of the code in the test cases of generic dispersion and collapse and stable and unstable rotating stars.

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Fully constrained, high-resolution shock-capturing, formulation of the Einstein-fluid equations in 2+1 dimensions - Accepted Manuscript
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Accepted/In Press date: 25 June 2021
e-pub ahead of print date: 26 July 2021
Published date: 26 July 2021
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Identifiers

Local EPrints ID: 453261
URI: http://eprints.soton.ac.uk/id/eprint/453261
DOI: doi:10.1103/PhysRevD.104.024061
ISSN: 2470-0010
PURE UUID: 39f46d50-af75-4b2e-b062-a52d6e806ac0
ORCID for Carsten Gundlach: ORCID iD orcid.org/0000-0001-9585-5375
ORCID for Patrick Bourg: ORCID iD orcid.org/0000-0003-0015-0861

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Date deposited: 11 Jan 2022 17:49
Last modified: 17 Mar 2024 02:51

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Contributors

Author: Carsten Gundlach ORCID iD
Author: Patrick Bourg ORCID iD
Author: Alex Davey

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