Dynamical systems approach to determine the far-from-equilibrium attractors for the Gubser flow

During the last decades it has been proven that relativistic hydrodynamics is a valuable phenomenological tool to describe high energy nuclear collisions. Recently, the research has focused on understanding the concept of hydrodynamical attractors within the different theories. Therefore, in this wo...

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Autores:
Cruz Camacho, Carlos Nikolás
Martínez Guerrero, Mauricio
Pinilla Beltrán, Edna Carolina
Tipo de recurso:
Fecha de publicación:
2019
Institución:
Universidad Nacional de Colombia
Repositorio:
Universidad Nacional de Colombia
Idioma:
spa
OAI Identifier:
oai:repositorio.unal.edu.co:unal/69319
Acceso en línea:
https://repositorio.unal.edu.co/handle/unal/69319
http://bdigital.unal.edu.co/70997/
Palabra clave:
5 Ciencias naturales y matemáticas / Science
53 Física / Physics
Relativistic Boltzmann equation
Kinetic theory
Hydrodynamization
Anisotropic hydrodynamics
Non-autonomous dynamical systems
Ecuación relativista de Boltzmann
Teoría cinética
Hidrodinización
Hidrodinámica anisotrópica
Sistemas dinámicos no
Autónomos
Rights
openAccess
License
Atribución-NoComercial 4.0 Internacional
Description
Summary:During the last decades it has been proven that relativistic hydrodynamics is a valuable phenomenological tool to describe high energy nuclear collisions. Recently, the research has focused on understanding the concept of hydrodynamical attractors within the different theories. Therefore, in this work the non-equilibrium attractors of systems undergoing Gubser flow within relativistic kinetic theory are studied. In doing so, we employ well-established methods of nonlinear dynamical systems which rely on finding the fixed points, investigating the structure of the flow diagrams of the evolution equations, and characterizing the basin of attraction using a Lyapunov function near the stable fixed points. We obtain the attractors of anisotropic hydrodynamics (aHydro), Israel-Stewart (IS) and transient fluid (DNMR) theories and show that they are indeed non-planar and the basin of attraction is essentially three-dimensional. The attractors of each hydrodynamical model are compared with the one obtained from the exact Gubser solution of the Boltzmann equation within the relaxation time approximation. We observe that the anisotropic hydrodynamics is able to match up to high numerical accuracy the attractor of the exact solution while the second order hydrodynamical theories fail to describe it. Our findings indicate that the reorganization of the expansion series carried out by anisotropic hydrodynamics resums the Knudsen and inverse Reynolds numbers to all orders, thus it can be understood as an effective theory for the far-from-equilibrium fluid dynamics.