Statistical symmetries of the Lundgren-Monin-Novikov hierarchy

Wacławczyk, Marta; Staffolani, Nicola; Oberlack, Martin; Rosteck, Andreas; Wilczek, Michael; Friedrich, Rudolf

doi:10.1103/physreve.90.013022

Cited by 41 publications

(90 citation statements)

References 20 publications

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“…This symmetry is present also in other methods used to describe stochastic fields, namely the multipoint correlation function approach and the multipoint probability density function approach; see [7,8], where also its physical meaning was discussed.…”

Section: Introductionmentioning

confidence: 98%

Reply to Frewer et al. Comments on Janocha et al. Lie Symmetry Analysis of the Hopf Functional-Differential Equation. Symmetry 2015, 7, 1536–1566

2016

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We reply to the comment by Frewer and Khujadze regarding our contribution “Lie Symmetry Analysis of the Hopf Functional-Differential Equation” (Symmetry 2015, 7(3), 1536). The method developed by the present authors considered the Lie group analysis of the Hopf equations with functional derivatives in the equation, not the integro-differential equations in general. It was based on previous contributions (Oberlack and Wacławczyk, Arch. Mech. 2006, 58; Wacławczyk and Oberlack, J. Math. Phys. 2013, 54). In fact, three of the symmetries calculated in (Symmetry 2015, 7(3), 1536) break due to internal consistency constrains and conditions imposed on test functions, the same concerns the corresponding symmetries derived by Frewer and Khujadze and another, spurious symmetry, which was not discussed by Frewer and Khujadze. As a result, the same set of symmetries is obtained with both approaches.

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Section: Introductionmentioning

confidence: 98%

Reply to Frewer et al. Comments on Janocha et al. Lie Symmetry Analysis of the Hopf Functional-Differential Equation. Symmetry 2015, 7, 1536–1566

2016

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“…As it was shown in Wacławczyk et al (2014) scaling of moments according to (234) transforms a PDF of a turbulent signal into a non-continuous PDF with delta function at the origin x = 0. Such function would correspond to a PDF of a turbulent signal interuppted by intervals where U = 0.…”

Section: Statistical Symmetries Of the Lmn Hierarchymentioning

confidence: 99%

“…This issue was investigated by Wacławczyk et al (2014), where the form of classical symmetries written in terms of PDF's was derived. Below, we shortly recall the findings.…”

Section: Symmetries Of the Lmn Hierarchy 521 Symmetries Of The Lmnmentioning

confidence: 99%

“…It was shown in Wacławczyk et al (2014) that the LMN equations are invariant with respect to the Galilean transformations t * = t, x * i = x i + u 0 t, u * i = u i + u 0 , where u 0 is a constant vector. However, the extended Galilean transformations T * 7 − T * 9 in (181), which read t * = t, x * = x + f (t) and U * = U + f ′ (t), where the vector f is time-dependent, was broken due to the formulation of the pressure term chosen for constructing the LMN hierarchy.…”

Section: Symmetries Of the Lmn Hierarchy 521 Symmetries Of The Lmnmentioning

confidence: 99%

“…The statistical symmetries of the LMN hiererchy were first identified in Wacławczyk et al (2014) and their derivation will be shortly recalled below. We discuss here a set of transformations of the PDFs under which the LMN equations (218) turn out to be invariant and which corresponds to the set of statistical symmetries (233) and (234) found for the MPCE, where the moments H are, respectively shifted by a constant and scaled.…”

Section: Statistical Symmetries Of the Lmn Hierarchymentioning

confidence: 99%

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Symmetries and their importance for statistical turbulence theory

Oberlack

Wacławczyk

Rosteck

et al. 2015

Mechanical Engineering Reviews

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PrefaceThe special importance of turbulence maybe comprehended by its ubiquity in innumerable natural and technical systems. Examples for natural turbulent flows are the atmospheric flow and the oceanic current which to calculate is a crucial point in climate research. Classical engineering application involving turbulence are the flows around airplanes or cars or turbulence within jet or reciprocating engines. Though supposed for more than hundred years, only with the advent of super computers it became apparent that the Navier-Stokes equations provide an excellent continuum mechanical model for turbulent flows. Still, the exclusive and direct application of the Navier-Stokes equations to practical flow problems at very high Reynolds numbers without invoking any additional assumptions is still several decades away.However, in most applications it is not at all necessary to know all the detailed fluctuations of velocity and pressure present in turbulent flows but for the most part statistical measures are sufficient. This was in fact the key idea of O. Reynolds who was the first to suggest a statistical description of turbulence. The Navier-Stokes equations, however, constitute a non-linear and, due to the pressure Poisson equation, a non-local set of equations. As an immediate consequence of this the equations for the mean or expectation values for velocity and pressure lead to an infinite set of statistical equations, or, if truncated at some level of statistics, an un-closed system is generated. Received 4 March 2015 AbstractThe present article is intended to give a broad overview and present details on the Lie symmetry induced statistical turbulence theory put forward by the authors and various other collaborators over the last twenty years. For this is crucial to understand that our present text-book knowledge proclaims that Lie symmetries such as Galilean transformation lie at the heart of fluid dynamics. These important properties also carry over to the statistical description of turbulence, i.e. to the Reynolds stress transport equations and its generalization, the multi-point correlation equations (MPCE). Interesting enough, the MPCE admit a much larger set of symmetries, in fact infinite dimensional, subsequently named statistical symmetries. Apart from the MPCE also the two other known complete theories of turbulence, the Lundgren-Monin-Novikov (LMN) hierarchy of probability density functions and the Hopf functional theory, share this property of admitting both classical mechanical and statistical Lie symmetries. As the Galilean transformation illuminates fundamental properties of classical mechanics, the new statistical symmetries mirror key properties of turbulence such as intermittency and non-gaussianity. After an introduction to Lie symmetries have been given, these facts will be detailed for all three turbulence approaches i.e. MPCE, LMN and Hopf approach. From a practical point of view, these new symmetries have important consequences for our understanding of turbulent scaling laws. The symmet...

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Statistical Symmetries in Second Order Turbulence Modeling

Putz,

Oberlack

2024

Springer Proceedings in Physics

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Statistical symmetries of the Lundgren-Monin-Novikov hierarchy

Cited by 41 publications

References 20 publications

Reply to Frewer et al. Comments on Janocha et al. Lie Symmetry Analysis of the Hopf Functional-Differential Equation. Symmetry 2015, 7, 1536–1566

Reply to Frewer et al. Comments on Janocha et al. Lie Symmetry Analysis of the Hopf Functional-Differential Equation. Symmetry 2015, 7, 1536–1566

Symmetries and their importance for statistical turbulence theory

Statistical Symmetries in Second Order Turbulence Modeling

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