Entropic-Skins Geometry to Describe Wall  Turbulence Intermittency

Queiros-Condé, Diogo; Carlier, Johan; Grosu, Lavinia; Stanislas, Michel

doi:10.3390/e17042198

Cited by 3 publications

(7 citation statements)

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“…One of these models, the entropic skin geometry (E.S.G. ), shown to be in agreement with other experiments [17,48], is an interpretation of this intermittency phenomenon achieved through a coupling between the multiscale fractal geometry and statistical intermittent analysis within the turbulence by assuming the existence of a certain hierarchy of correlated fractal structures, characterizing the dynamics of fluctuation levels (skins). Each fluctuation level of the order p has been associated with a fluctuating field Ω p , representing a structure of dimension ∆ p , included in the field Ω p−dp of dimension ∆ p−dp , such as Ω p−dp ⊃ Ω p with ∆ p−dp < ∆ p .…”

Section: Entropic Skis Geometry (Esg) To Describe Intermittencysupporting

confidence: 83%

“…In the statistical approach, the value of a structure function < ε(r) p > is given by its "active part", offering two contributions; the first one − ε(r) p is the average energy dissipation rate over the actual active part of the field, and the second f p (r) is the volume fraction, which indicates an intermittency factor and allows for the "lacunary aspect" of energy dissipation [3,20]. Thus, we would have:…”

Section: Entropic Skis Geometry (Esg) To Describe Intermittencymentioning

confidence: 99%

“…Kolmogorov's theory in developed turbulence (K41) assumes that turbulence is statistically homogeneous (invariant due to spatial translation, far from limits), isotropic (invariant due to rotation), self-similar (invariant due to scale expansion) and stationary (invariant due to time translation) [1][2][3]. According to Kolmogorov's theory, the developed turbulence can be described using the structure functions of dissipated energy < ε(r) p > and velocity < ∆V(r) p >, with ε(r) the rate of energy dissipation per unit mass averaging over an r-dimensional ball and ∆V(r) the velocity fluctuation V between two points separated by a distance of r.…”

Section: Introduction 1statistical Intermittency: From the Theory Of ...mentioning

confidence: 99%

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Fractal Geometric Model for Statistical Intermittency Phenomenon

Tarraf,

Queiros-Condé,

Ribeiro

et al. 2023

Entropy

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The phenomenon of intermittency has remained a theoretical concept without any attempts to approach it geometrically with the use of a simple visualization. In this paper, a particular geometric model of point clustering approaching the Cantor shape in 2D, with a symmetry scale θ being an intermittency parameter, is proposed. To verify its ability to describe intermittency, to this model, we applied the entropic skin theory concept. This allowed us to obtain a conceptual validation. We observed that the intermittency phenomenon in our model was adequately described with the multiscale dynamics proposed by the entropic skin theory, coupling the fluctuation levels that extended between two extremes: the bulk and the crest. We calculated the reversibility efficiency γ with two different methods: statistical and geometrical analyses. Both efficiency values, γstat and γgeo, showed equality with a low relative error margin, which actually validated our suggested fractal model for intermittency. In addition, we applied the extended self-similarity (E.S.S.) to the model. This highlighted the intermittency phenomenon as a deviation from the homogeneity assumed by Kolmogorov in turbulence.

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Section: Entropic Skis Geometry (Esg) To Describe Intermittencysupporting

confidence: 83%

Section: Entropic Skis Geometry (Esg) To Describe Intermittencymentioning

confidence: 99%

Section: Introduction 1statistical Intermittency: From the Theory Of ...mentioning

confidence: 99%

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Fractal Geometric Model for Statistical Intermittency Phenomenon

Tarraf,

Queiros-Condé,

Ribeiro

et al. 2023

Entropy

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“…The scale-entropy diffusion equation (hereafter SED equation) permits to quantify the properties of multi-scale phenomena through scale-space [6] and has been applied mostly to describe turbulence [11] turbulent combustion [12] and sprays [13]. The scale-entropy (S) represents an evolutive potential, which is traduced by the capacity to fill the space of a phenomenon (the higher the scale-entropy, the less the phenomenon is disorganized).…”

Section: Scale-space Dynamics Using Scale Entropy Diffusion Equationmentioning

confidence: 99%

A scale-entropy diffusion equation to explore scale-dependent fractality

Ribeiro¹,

Queiros-Condé²

2017

Proc. R. Soc. A.

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scale-space (pure fractal), however, numerous works showed that fractal dimension was rather a multi-scale phenomena, thus a scale-and time-dependent quantity.In order to grasp all the complexity of multi-scale behaviours, a scale-entropy diffusion equation has been introduced [6]. Based on the scale-entropy diffusion equation and especially on the scale-entropy sink term, our aim is in the first part of the work, to explore several specific cases of the equation which would correspond to real multi-scale behaviours: (i) power law form for the scale-entropy sink term and (ii) polynomial form for the scale-entropy sink term. This leads to an interesting structure of what we called the 'fractal modes' of a multi-scale phenomena. In the second part of the paper, (iii) we numerically explore the intrinsic log-periodic structure of deterministic fractals, doing that, (iv) we develop a new measurement of fractal dimension based on a precise determination of transition scales, and (v) we introduce a new fractal diagram to show how scale, scale-dependent fractal dimension and scale-entropy sink are correlated. This gives us an original tool to interpret all the complexity of multi-scale behaviours. Finally, (vi) we build deterministic scale-dependent fractals with some specified properties, verified in the framework of the scale-entropy diffusion equation.The pure fractal geometry requires a strict self-similarity in the log-log scale analysis. Nevertheless, departure from linearity is widely popular in 'real' fractal geometries. Results from experiments on diverse phenomena (not thresholding or noise) [7,8] seems to behave as a parabolic fractal [9] and not really as a pure fractal. The parabolic fractal consists in an equipartition [10] of the scale-entropy sink through scale-space, but it can take any form leading to what we can call 'dissipative' fractals or 'cumulative' fractals. The idea of 'impure Von Koch' with altered fractal dimensions (possessing different internal similarities) was studied, for example, in [3], in our case, these similarities change at each scale of observation leading to scale-dependent geometry.

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“…and Where are the fractal support and its location? The field of fractals in materials is well documented (Carpinteri, 1994;Hähner et al, 1998) and the reflections about fractal geometry (Mandelbrot, 1975;Le Méhauté et al, 1998), entropy minimisation and constructal theory (Bejan, 2006;Wechsatol et al, 2004) and geometrical structure of entropy generation (Queiros-Condé, 2003;Queiros-Condé et al, 2015a, 2015bCanivet et al, 2016) lead us to the exergy equation for a better understanding of mechanical fatigue.…”

Section: Introductionmentioning

confidence: 99%

An exergetic approach for materials fatigue

Ribeiro

Queiros-Condé

Grosu

et al. 2017

IJEX

Self Cite

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An entropy approach has been recently developed, based on the irreversible thermodynamics and entropy production. It has been observed that, for low cycle fatigue, metals undergoing cyclic load reach fracture, at a certain level of entropy production called fracture fatigue entropy (FFE) (Naderi and Khonsari, 2010), solely dependent on the material. Until now, we only used the two principles of thermodynamics separately to follow the behaviour of a solid continuum problem as low cycle fatigue. We propose here to use the two laws of thermodynamics together via the Gouy-Stodola equation and the concept of exergy to provide a new description for metals undergoing low cycle fatigue.

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Entropic-Skins Geometry to Describe Wall Turbulence Intermittency

Cited by 3 publications

References 29 publications

Fractal Geometric Model for Statistical Intermittency Phenomenon

Fractal Geometric Model for Statistical Intermittency Phenomenon

A scale-entropy diffusion equation to explore scale-dependent fractality

An exergetic approach for materials fatigue

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