Analytic approach to the relaxation time approximation Boltzmann attractor

Inês Aniceto; Jorge Noronha; Michał Spaliński

doi:10.1103/PhysRevD.111.076025

Analytic approach to the relaxation time approximation Boltzmann attractor

Inês Aniceto
, Jorge Noronha
, Michał Spaliński

Physics

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

Abstract

We reformulate the Boltzmann equation in the relaxation time approximation undergoing Bjorken flow in terms of a novel partial differential equation for the generating function of the moments of the distribution function. This is used to obtain a series expansion of this system's far-from-equilibrium attractor. This expansion possesses a finite radius of convergence, which proves the existence of the attractor. Furthermore, the series can be analytically continued to late times and we find that this procedure reproduces the known values of shear viscosity and other transport coefficients to high accuracy. We also provide a simple approximate analytic expression that describes the attractor in the entire domain of interest for studies of quark-gluon plasma dynamics.

Original language	English (US)
Article number	076025
Journal	Physical Review D
Volume	111
Issue number	7
DOIs	https://doi.org/10.1103/PhysRevD.111.076025
State	Published - Apr 1 2025

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Nuclear and High Energy Physics

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10.1103/PhysRevD.111.076025

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title = "Analytic approach to the relaxation time approximation Boltzmann attractor",

abstract = "We reformulate the Boltzmann equation in the relaxation time approximation undergoing Bjorken flow in terms of a novel partial differential equation for the generating function of the moments of the distribution function. This is used to obtain a series expansion of this system's far-from-equilibrium attractor. This expansion possesses a finite radius of convergence, which proves the existence of the attractor. Furthermore, the series can be analytically continued to late times and we find that this procedure reproduces the known values of shear viscosity and other transport coefficients to high accuracy. We also provide a simple approximate analytic expression that describes the attractor in the entire domain of interest for studies of quark-gluon plasma dynamics.",

author = "In{\^e}s Aniceto and Jorge Noronha and Micha{\l} Spali{\'n}ski",

note = "We would like to thank M. Strickland for very useful comments on the manuscript. I.\textbackslash{}u2009A. and J.\textbackslash{}u2009N. thank KITP Santa Barbara for its hospitality during \textbackslash{}u201CThe Many Faces of Relativistic Fluid Dynamics\textbackslash{}u201D Program, where part of this work was conducted. I.\textbackslash{}u2009A. and M.\textbackslash{}u2009S. thank the Isaac Newton Institute for hosting them during the program \textbackslash{}u201CApplicable Resurgent Asymptotics\textbackslash{}u201D during the early stages of the work. I.\textbackslash{}u2009A. has been supported by the UK EPSRC Early Career Fellowship EP/S004076/1. M.\textbackslash{}u2009S. was supported by the National Science Centre, Poland, under Grant No. 2021/41/B/ST2/02909. J.\textbackslash{}u2009N. is partly supported by the U.S. Department of Energy, Office of Science, Office for Nuclear Physics under Award No. DE-SC0023861. This research was partly supported by the National Science Foundation under Grant No. NSF PHY-1748958.",

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AU - Spaliński, Michał

N1 - We would like to thank M. Strickland for very useful comments on the manuscript. I.\u2009A. and J.\u2009N. thank KITP Santa Barbara for its hospitality during \u201CThe Many Faces of Relativistic Fluid Dynamics\u201D Program, where part of this work was conducted. I.\u2009A. and M.\u2009S. thank the Isaac Newton Institute for hosting them during the program \u201CApplicable Resurgent Asymptotics\u201D during the early stages of the work. I.\u2009A. has been supported by the UK EPSRC Early Career Fellowship EP/S004076/1. M.\u2009S. was supported by the National Science Centre, Poland, under Grant No. 2021/41/B/ST2/02909. J.\u2009N. is partly supported by the U.S. Department of Energy, Office of Science, Office for Nuclear Physics under Award No. DE-SC0023861. This research was partly supported by the National Science Foundation under Grant No. NSF PHY-1748958.

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N2 - We reformulate the Boltzmann equation in the relaxation time approximation undergoing Bjorken flow in terms of a novel partial differential equation for the generating function of the moments of the distribution function. This is used to obtain a series expansion of this system's far-from-equilibrium attractor. This expansion possesses a finite radius of convergence, which proves the existence of the attractor. Furthermore, the series can be analytically continued to late times and we find that this procedure reproduces the known values of shear viscosity and other transport coefficients to high accuracy. We also provide a simple approximate analytic expression that describes the attractor in the entire domain of interest for studies of quark-gluon plasma dynamics.

AB - We reformulate the Boltzmann equation in the relaxation time approximation undergoing Bjorken flow in terms of a novel partial differential equation for the generating function of the moments of the distribution function. This is used to obtain a series expansion of this system's far-from-equilibrium attractor. This expansion possesses a finite radius of convergence, which proves the existence of the attractor. Furthermore, the series can be analytically continued to late times and we find that this procedure reproduces the known values of shear viscosity and other transport coefficients to high accuracy. We also provide a simple approximate analytic expression that describes the attractor in the entire domain of interest for studies of quark-gluon plasma dynamics.

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Analytic approach to the relaxation time approximation Boltzmann attractor

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