Relativistic fluid dynamics: physics for many different scales
Relativistic fluid dynamics: physics for many different scales
The relativistic fluid is a highly successful model used to describe the dynamics of many-particle systems moving at high velocities and/or in strong gravity. It takes as input physics from microscopic scales and yields as output predictions of bulk, macroscopic motion. By inverting the process—e.g., drawing on astrophysical observations—an understanding of relativistic features can lead to insight into physics on the microscopic scale. Relativistic fluids have been used to model systems as “small” as colliding heavy ions in laboratory experiments, and as large as the Universe itself, with “intermediate” sized objects like neutron stars being considered along the way. The purpose of this review is to discuss the mathematical and theoretical physics underpinnings of the relativistic (multi-) fluid model. We focus on the variational principle approach championed by Brandon Carter and collaborators, in which a crucial element is to distinguish the momenta that are conjugate to the particle number density currents. This approach differs from the “standard” text-book derivation of the equations of motion from the divergence of the stress-energy tensor in that one explicitly obtains the relativistic Euler equation as an “integrability” condition on the relativistic vorticity. We discuss the conservation laws and the equations of motion in detail, and provide a number of (in our opinion) interesting and relevant applications of the general theory. The formalism provides a foundation for complex models, e.g., including electromagnetism, superfluidity and elasticity—all of which are relevant for state of the art neutron-star modelling.
Andersson, Nils
2dd6d1ee-cefd-478a-b1ac-e6feedafe304
Comer, G.L.
b34e5164-7f70-4ba1-b04f-2f0ed9d19d05
24 June 2021
Andersson, Nils
2dd6d1ee-cefd-478a-b1ac-e6feedafe304
Comer, G.L.
b34e5164-7f70-4ba1-b04f-2f0ed9d19d05
Andersson, Nils and Comer, G.L.
(2021)
Relativistic fluid dynamics: physics for many different scales.
Living Reviews in Relativity, 24, [3].
(doi:10.1007/s41114-021-00031-6).
Abstract
The relativistic fluid is a highly successful model used to describe the dynamics of many-particle systems moving at high velocities and/or in strong gravity. It takes as input physics from microscopic scales and yields as output predictions of bulk, macroscopic motion. By inverting the process—e.g., drawing on astrophysical observations—an understanding of relativistic features can lead to insight into physics on the microscopic scale. Relativistic fluids have been used to model systems as “small” as colliding heavy ions in laboratory experiments, and as large as the Universe itself, with “intermediate” sized objects like neutron stars being considered along the way. The purpose of this review is to discuss the mathematical and theoretical physics underpinnings of the relativistic (multi-) fluid model. We focus on the variational principle approach championed by Brandon Carter and collaborators, in which a crucial element is to distinguish the momenta that are conjugate to the particle number density currents. This approach differs from the “standard” text-book derivation of the equations of motion from the divergence of the stress-energy tensor in that one explicitly obtains the relativistic Euler equation as an “integrability” condition on the relativistic vorticity. We discuss the conservation laws and the equations of motion in detail, and provide a number of (in our opinion) interesting and relevant applications of the general theory. The formalism provides a foundation for complex models, e.g., including electromagnetism, superfluidity and elasticity—all of which are relevant for state of the art neutron-star modelling.
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Accepted/In Press date: 22 January 2021
Published date: 24 June 2021
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Local EPrints ID: 456548
URI: http://eprints.soton.ac.uk/id/eprint/456548
ISSN: 1433-8351
PURE UUID: 56fca3a6-b526-4f6c-9f6d-72d01bab3e6e
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Date deposited: 04 May 2022 17:26
Last modified: 17 Mar 2024 02:47
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G.L. Comer
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