A statistical mechanics approach to mixing in stratified fluids

Venaille, Antoine; Gostiaux, Louis; Sommeria, Joël

doi:10.1017/jfm.2016.721

Cited by 14 publications

(18 citation statements)

References 90 publications

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“…The second definition can be found in Refs. [10,21,23] and is based on the background potential energy, so that it should be more relevant in terms of quantifying the irreversible mixing. The instantaneous mixing efficiency reads…”

Section: B Mixing Efficienciesmentioning

confidence: 99%

Harmonic to subharmonic transition of the Faraday instability in miscible fluids

2019

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When a stable stratification between two miscible fluids is excited by a vertical and periodic forcing, a turbulent mixing zone can develop, triggered by the Faraday instability. The mixing zone grows and saturates to a recently predicted final value L sat [Gréa and Ebo Adou, J. Fluid Mech. 837, 293 (2018)] when resonance conditions are no longer fulfilled. Notably, it is expected from the Mathieu stability diagram that the instability may evolve from a harmonic to a subharmonic regime for particular initial conditions. This transition is evidenced here in the full inhomogeneous system using direct numerical simulations with 1024 3 points: the analysis of one-point statistics and spectra reveals that turbulence is greatly enhanced after the transition, while the global anisotropy of both the velocity and concentration fields is significantly reduced. Furthermore, using the concept of sorted density field, we compute the background potential energy e b p of the flow, which increases only after the transition as a signature of irreversible mixing. While the gain in e b p strongly depends on the control parameters of the instability, the cumulative mixing efficiency is more robust. At saturation of the instability, available potential energy is partially released in the flow as background potential energy. Finally, it is shown numerically that for fixed parameters, a multiple-frequency forcing can modify the duration of the harmonic regime without significantly altering the asymptotic state.

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Section: B Mixing Efficienciesmentioning

confidence: 99%

Harmonic to subharmonic transition of the Faraday instability in miscible fluids

2019

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“…Alternatively, Balmforth et al (1998) proposed that the relationship between buoyancy flux and stratification should be 'N-shaped', with a return to an increase in buoyancy flux with increasing and sufficiently large stratification. Indeed, the possibly non-monotonic dependence of irreversible buoyancy flux on external parameters is a very active area of research controversy (see e.g Venayagamoorthy & Koseff (2016); Venaille et al (2016); Maffioli et al (2016)). Importantly however, the fundamental physical mechanisms leading to either the formation or the maintenance of layered density distributions are still quite open.…”

Section: Introductionmentioning

confidence: 99%

Layer formation in horizontally forced stratified turbulence: connecting exact coherent structures to linear instabilities

2017

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We consider turbulence in a stratified 'Kolmogorov' flow, driven by horizontal shear in the form of sinusoidal body forcing in the presence of an imposed background linear stable stratification in the third direction. This flow configuration allows the controlled investigation of the formation of coherent structures, which here organise the flow into horizontal layers by inclining the background shear as the strength of the stratification is increased. By numerically converging exact steady states from direct numerical simulations of chaotic flow, we show, for the first time, a robust connection between linear theory predicting instabilities from infinitesimal perturbations to the robust finite amplitude nonlinear layered state observed in the turbulence. We investigate how the observed vertical length scales are related to the primary linear instabilities and compare to previously considered examples of shear instability leading to layer formation in other horizontally sheared flows.

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“…Recently, statistical mechanics arguments developed by Venaille et al (2017), assuming infinite Reynolds and Péclet numbers, suggest that some appropriate measure of the overall mixing efficiency, characterising the fraction of the kinetic energy loss by the fluid that leads an irreversibly gain in the potential energy due to mixing, varies non-monotonically with the overall gradient Richardson number if the background buoyancy profile contains a layered structure, whereas such a mixing efficiency asymptotes to a constant value of approximately 0.25 if the background buoyancy gradient is uniform. This suggests that the mixing properties of a sharp density interface may vary significantly from that of a linearly varying density profile (e.g.…”

Section: Introductionmentioning

confidence: 99%

Diapycnal mixing in layered stratified plane Couette flow quantified in a tracer-based coordinate

et al. 2017

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The mixing properties of statically stable density interfaces subject to imposed vertical shear are studied using direct numerical simulations of stratified plane Couette flow. The simulations are designed to investigate possible self-maintaining mechanisms of sharp density interfaces motivated by Phillips’ argument (Deep-Sea Res., vol. 19, 1972, pp. 79–81) by which layers and interfaces can spontaneously form due to vertical variations of diapycnal flux. At the start of each simulation, a sharp density interface with the same initial thickness is introduced at the midplane between two flat, horizontal walls counter-moving at velocities$\pm U_{w}$. Particular attention is paid to the effects of varying Prandtl number$\mathit{Pr}\equiv \unicode[STIX]{x1D708}/\unicode[STIX]{x1D705}$, where$\unicode[STIX]{x1D708}$and$\unicode[STIX]{x1D705}$are the molecular kinematic viscosity and diffusivity respectively, over two orders of magnitude from 0.7, 7 and 70. Varying$\mathit{Pr}$enables the system to access a considerable range of characteristic turbulent Péclet numbers$\mathit{Pe}_{\ast }\equiv {\mathcal{U}}_{\ast }{\mathcal{L}}_{\ast }/\unicode[STIX]{x1D705}$, where${\mathcal{U}}_{\ast }$and${\mathcal{L}}_{\ast }$are characteristic velocity and length scales, respectively, of the motion which acts to ‘scour’ the density interface. The dynamics of the interface varies with the stability of the interface which is characterised by a bulk Richardson number$\mathit{Ri}\,\equiv \,b_{0}h/U_{w}^{2}$, where$b_{0}$is half the initial buoyancy difference across the interface and$h$is the half-height of the channel. Shear-induced turbulence occurs at small$\mathit{Ri}$, whereas internal waves propagating on the interface dominate at large$\mathit{Ri}$. For a highly stable (i.e. large$\mathit{Ri}$) interface at sufficiently large$\mathit{Pe}_{\ast }$, the complex interfacial dynamics allows the interface to remain sharp. This ‘self-sharpening’ is due to the combined effects of the ‘scouring’ induced by the turbulence external to the interface and comparatively weak molecular diffusion across the core region of the interface. The effective diapycnal diffusivity and irreversible buoyancy flux are quantified in the tracer-based reference coordinate proposed by Winters & D’Asaro (J. Fluid Mech., vol. 317, 1996, pp. 179–193) and Nakamura (J. Atmos. Sci., vol. 53, 1996, pp. 1524–1537), which enables a detailed investigation of the self-sharpening process by analysing the local budget of buoyancy gradient in the reference coordinate. We further discuss the dependence of the effective diffusivity and overall mixing efficiency on the characteristic parameters of the flow, such as the buoyancy Reynolds number and the local gradient Richardson number, and highlight the possible role of the molecular properties of fluids on diapycnal mixing.

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A statistical mechanics approach to mixing in stratified fluids

Cited by 14 publications

References 90 publications

Harmonic to subharmonic transition of the Faraday instability in miscible fluids

Harmonic to subharmonic transition of the Faraday instability in miscible fluids

Layer formation in horizontally forced stratified turbulence: connecting exact coherent structures to linear instabilities

Diapycnal mixing in layered stratified plane Couette flow quantified in a tracer-based coordinate

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