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Non-perturbative Renormalization Group Approach to Some Out-of-Equilibrium Systems = Diffusive Epidemic Process and Fully Developed Turbulence /

Record Type:	Language materials, printed : Monograph/item
Title/Author:	Non-perturbative Renormalization Group Approach to Some Out-of-Equilibrium Systems/ by Malo Tarpin.
Reminder of title:	Diffusive Epidemic Process and Fully Developed Turbulence /
Author:	Tarpin, Malo.
Description:	XV, 207 p. 21 illus.online resource. :
Contained By:	Springer Nature eBook
Subject:	Statistical physics. -
Online resource:	https://doi.org/10.1007/978-3-030-39871-2
ISBN:	9783030398712

Non-perturbative Renormalization Group Approach to Some Out-of-Equilibrium Systems = Diffusive Epidemic Process and Fully Developed Turbulence /
Tarpin, Malo.

Non-perturbative Renormalization Group Approach to Some Out-of-Equilibrium SystemsDiffusive Epidemic Process and Fully Developed Turbulence /[electronic resource] :by Malo Tarpin. - 1st ed. 2020. - XV, 207 p. 21 illus.online resource. - Springer Theses, Recognizing Outstanding Ph.D. Research,2190-5053. - Springer Theses, Recognizing Outstanding Ph.D. Research,.

General Introduction -- Universal Behaviors in the Diffusive Epidemic Process and in Fully Developed Turbulence -- Introduction to Non-perturbative Renormalization Group for Out-of-Equilibrium Field Theories -- Study of the Absorbing Phase Transition in DEP -- Breaking of Scale Invariance in Correlation Functions of Turbulence -- General Conclusion -- Appendices.

This thesis presents the application of non-perturbative, or functional, renormalization group to study the physics of critical stationary states in systems out-of-equilibrium. Two different systems are thereby studied. The first system is the diffusive epidemic process, a stochastic process which models the propagation of an epidemic within a population. This model exhibits a phase transition peculiar to out-of-equilibrium, between a stationary state where the epidemic is extinct and one where it survives. The present study helps to clarify subtle issues about the underlying symmetries of this process and the possible universality classes of its phase transition. The second system is fully developed homogeneous isotropic and incompressible turbulence. The stationary state of this driven-dissipative system shows an energy cascade whose phenomenology is complex, with partial scale-invariance, intertwined with what is called intermittency. In this work, analytical expressions for the space-time dependence of multi-point correlation functions of the turbulent state in 2- and 3-D are derived. This result is noteworthy in that it does not rely on phenomenological input except from the Navier-Stokes equation and that it becomes exact in the physically relevant limit of large wave-numbers. The obtained correlation functions show how scale invariance is broken in a subtle way, related to intermittency corrections.

ISBN: 9783030398712

Standard No.: 10.1007/978-3-030-39871-2doiSubjects--Topical Terms:

528048
Statistical physics.

LC Class. No.: QC174.7-175.36

Dewey Class. No.: 530.1

Non-perturbative Renormalization Group Approach to Some Out-of-Equilibrium Systems = Diffusive Epidemic Process and Fully Developed Turbulence /
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520 $a This thesis presents the application of non-perturbative, or functional, renormalization group to study the physics of critical stationary states in systems out-of-equilibrium. Two different systems are thereby studied. The first system is the diffusive epidemic process, a stochastic process which models the propagation of an epidemic within a population. This model exhibits a phase transition peculiar to out-of-equilibrium, between a stationary state where the epidemic is extinct and one where it survives. The present study helps to clarify subtle issues about the underlying symmetries of this process and the possible universality classes of its phase transition. The second system is fully developed homogeneous isotropic and incompressible turbulence. The stationary state of this driven-dissipative system shows an energy cascade whose phenomenology is complex, with partial scale-invariance, intertwined with what is called intermittency. In this work, analytical expressions for the space-time dependence of multi-point correlation functions of the turbulent state in 2- and 3-D are derived. This result is noteworthy in that it does not rely on phenomenological input except from the Navier-Stokes equation and that it becomes exact in the physically relevant limit of large wave-numbers. The obtained correlation functions show how scale invariance is broken in a subtle way, related to intermittency corrections.
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