Hydrodynamic gradient expansion diverges beyond Bjorken flow
Hydrodynamic gradient expansion diverges beyond Bjorken flow
The gradient expansion is the fundamental organizing principle underlying relativistic hydrodynamics, yet understanding its convergence properties for general nonlinear flows has posed a major challenge. We introduce a simple method to address this question in a class of fluids modeled by Israel-Stewart-type relaxation equations. We apply it to (1+1)-dimensional flows and provide numerical evidence for factorially divergent gradient expansions. This generalizes results previously only obtained for (0+1)-dimensional comoving flows, notably Bjorken flow. We also demonstrate that the only known nontrivial case of a convergent hydrodynamic gradient expansion at the nonlinear level relies on Bjorken flow symmetries and becomes factorially divergent as soon as these are relaxed. Finally, we show that factorial divergence can be removed using a momentum space cutoff, which generalizes a result obtained earlier in the context of linear response.
Heller, Michal P.
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Serantes, Alexandre
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Spaliński, Michał
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Svensson, Viktor
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Withers, Benjamin
e510375b-c5d2-4d5f-bd68-40ace13f0ec9
25 March 2022
Heller, Michal P.
5b6c6d3e-4731-414d-8556-bd8604ce5377
Serantes, Alexandre
e19687f5-de76-4cb3-9afa-c9d843c3f5e2
Spaliński, Michał
3fabf22d-7873-492c-8bc6-6101c914c2b0
Svensson, Viktor
8a239c71-2e14-4d40-9aa1-2dc260d05507
Withers, Benjamin
e510375b-c5d2-4d5f-bd68-40ace13f0ec9
Heller, Michal P., Serantes, Alexandre, Spaliński, Michał, Svensson, Viktor and Withers, Benjamin
(2022)
Hydrodynamic gradient expansion diverges beyond Bjorken flow.
Physical Review Letters, 128 (12), [122302].
(doi:10.1103/PhysRevLett.128.122302).
Abstract
The gradient expansion is the fundamental organizing principle underlying relativistic hydrodynamics, yet understanding its convergence properties for general nonlinear flows has posed a major challenge. We introduce a simple method to address this question in a class of fluids modeled by Israel-Stewart-type relaxation equations. We apply it to (1+1)-dimensional flows and provide numerical evidence for factorially divergent gradient expansions. This generalizes results previously only obtained for (0+1)-dimensional comoving flows, notably Bjorken flow. We also demonstrate that the only known nontrivial case of a convergent hydrodynamic gradient expansion at the nonlinear level relies on Bjorken flow symmetries and becomes factorially divergent as soon as these are relaxed. Finally, we show that factorial divergence can be removed using a momentum space cutoff, which generalizes a result obtained earlier in the context of linear response.
Text
PhysRevLett.128.122302
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More information
Accepted/In Press date: 28 February 2022
e-pub ahead of print date: 25 March 2022
Published date: 25 March 2022
Additional Information:
v1: 9 pages, 4 figures; v2: minor clarifications added, version published in PRL
Identifiers
Local EPrints ID: 456944
URI: http://eprints.soton.ac.uk/id/eprint/456944
PURE UUID: dd06e3f6-bde2-4954-96f8-7b8cbd273004
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Date deposited: 17 May 2022 17:03
Last modified: 06 Jun 2024 01:27
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Contributors
Author:
Michal P. Heller
Author:
Alexandre Serantes
Author:
Michał Spaliński
Author:
Viktor Svensson
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