Scaling behavior in interacting systems: joint effect of anisotropy and compressibility

Scaling behavior in interacting systems: joint effect of anisotropy and compressibility

Motivated by the ubiquity of turbulent flows in realistic conditions, effects of turbulent advection on two models of classical non-linear systems are investigated. In particular, we analyze model A (according to the Hohenberg–Halperin classification [P.C. Hohenberg, B.I. Halperin, Rev. Mod. Phys. 4...

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Bibliographic Details
Published in:The European physical journal. B, Condensed matter physics Vol. 91; no. 11
Main Authors: Hnatič, Michal, Kalagov, Georgii, Lučivjanský, Tomáš
Format: Journal Article
Language:English
Published: Berlin/Heidelberg Springer Berlin Heidelberg 01-11-2018
Springer
Springer Nature B.V
Subjects:
Anisotropy
Complex Systems
Compressibility effects
Computational fluid dynamics
Condensed Matter Physics
Fluid- and Aerodynamics
Linear systems
Nonlinear systems
Normal distribution
Order parameters
Percolation
Physics
Physics and Astronomy
Regular Article
Scaling
Solid State Physics
Statistical analysis
Turbulence
Variation
Velocity
Velocity distribution
Statistical and Nonlinear Physics
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Summary:Motivated by the ubiquity of turbulent flows in realistic conditions, effects of turbulent advection on two models of classical non-linear systems are investigated. In particular, we analyze model A (according to the Hohenberg–Halperin classification [P.C. Hohenberg, B.I. Halperin, Rev. Mod. Phys. 49 , 435 (1977)]) of a non-conserved order parameter and a model of the direct bond percolation process. Having two paradigmatic representatives of distinct stochastic dynamics, our aim is to elucidate to what extent velocity fluctuations affect their scaling behavior. The main emphasis is put on an interplay between anisotropy and compressibility of the velocity flow on their respective scaling regimes. Velocity fluctuations are generated by means of the Kraichnan rapid-change model, in which the anisotropy is due to a distinguished spatial direction n and a correlator of the velocity field obeys the Gaussian distribution law with prescribed statistical properties. As the main theoretical tool, the field-theoretic perturbative renormalization group is adopted. Actual calculations are performed in the leading (one-loop) approximation. Having obtained infrared stable asymptotic regimes, we have found four possible candidates for macroscopically observable behavior for each model. In contrast to the isotropic case, anisotropy brings about enhancement of non-linearities and non-trivial regimes are proved to be more stable.
ISSN:1434-6028
1434-6036
DOI:10.1140/epjb/e2018-90308-1