Turbulent mixing and transition criteria of flows induced by hydrodynamic instabilities

Zhou, Ye; Clark, Timothy T.; Clark, Daniel; Glendinning, S. G.; Skinner, M. Aaron; Huntington, C. M.; Hurricane, O. A.; Dimits, A. M.; Remington, B. A.

doi:10.1063/1.5088745

Cited by 189 publications

(90 citation statements)

References 574 publications

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“…It is apparent from these review papers that both RM and RT are strongly influenced by the initial conditions and this needs to be taken into account if any form of engineering modelling is used. The analysis given in this paper describes, for a particular case, a way of modelling the transition to turbulence, an issue of significant current interest according to Zhou et al [21].…”

Section: Introductionmentioning

confidence: 99%

Early Time Modifications to the Buoyancy-Drag Model for Richtmyer–Meshkov Mixing

Youngs

Thornber

2020

Journal of Fluids Engineering

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The Buoyancy-Drag model is a simple model, based on ordinary differential equations, for estimating the growth in the width of a turbulent mixing zone at an interface between fluids of different density due to Richtmyer-Meshkov and Rayleigh-Taylor instabilities. The model is calibrated to give the required self-similar behaviour for mixing in simple situations. However, the early stages of the mixing process are very dependent on the initial conditions and modifications to the Buoyancy-Drag model are then needed to obtain correct results. In a recent paper, Thornber et al. [Phys. Fluids. 29 (2017) 105107], a range of three-dimensional simulation techniques were used to calculate the evolution of the mixing zone integral width due to single-shock Richtmyer-Meshkov mixing from narrowband initial random perturbations. Further analysis of the results of these simulations gives greater insight into the transition from the initial linear behaviour to late-time self-similar mixing and provides a way of modifying the Buoyancy-Drag model to treat the initial conditions accurately. Higher resolution simulations are used to calculate the early time behavior more accurately and compare with a multi-mode model based on the impulsive linear theory. The analysis of the iLES data also gives a new method for estimating the growth exponent , theta (mixing zone width ~ t^theta), which is suitable for simulations which do not fully reach the self-state. The estimates of theta are consistent with the theoretical model of Elbaz & Shvarts [Physics of Plasmas (2018), 25, 062126].

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Section: Introductionmentioning

confidence: 99%

Early Time Modifications to the Buoyancy-Drag Model for Richtmyer–Meshkov Mixing

Youngs

Thornber

2020

Journal of Fluids Engineering

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“…In general, the equations presented in the previous paragraph are used to determine its value, but there are a range of methods that have been applied in the literature 12 . Values of ∼ 0.05 found in experiments 12,14 , but values of 0.027 are found in 3D numerical simulations 9,12,15,16 . The initial spectrum of the perturbations can have a huge influence on the value of α obtained, with a difference of a factor of 2 to 3 11,17 as a result of the initial spectrum.…”

Section: Introductionmentioning

confidence: 91%

“…At late times this just reduces the model that comes from dimensional analysis 7 . As the late time limit is hard to achieve 9 , calculations of α using this method can depend heavily on the determination of the virtual origin, i.e. calculation h 0 .…”

Section: Introductionmentioning

confidence: 99%

“…The value of α has been the subject of much study [9][10][11][12][13] . In general, the equations presented in the previous paragraph are used to determine its value, but there are a range of methods that have been applied in the literature 12 .…”

Section: Introductionmentioning

confidence: 99%

“…This difference may be attributed to the importance of mass diffusion in different cases. For an overall review, see Zhou et al 9 .…”

Section: Introductionmentioning

confidence: 99%

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Self-similar solutions of asymmetric Rayleigh-Taylor mixing

Hillier

2020

Physics of Fluids

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The late nonlinear phase of the Rayleigh-Taylor instability is characterised by the self-similar expansion of the instability mixing layer given at late times by h ≈ αAgt 2. In this paper we present a new model of this mixing layer, based on a piecewise step function approximation where the main constraint imposed is conservation of mass. This model is used to predict the structuring of the mean density of the layer and the asymmetry of the layer for a given Atwood number. By comparing to experimental data and simulation results we confirmed the predictions of the model for the asymmetry of the α values. Our model leads to a simple correction to the formulation of the expansion of the mixing layer which is consistent with an α for a given system that is independent of the density difference for both immiscible fluids and miscible fluids with low mass diffusion. As the model predicts the mean density profile, it can be used to state the energy released by the instability.

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Buoyancy-Driven Instability and Growth

Dou

2022

Origin of Turbulence

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Turbulent mixing and transition criteria of flows induced by hydrodynamic instabilities

Cited by 189 publications

References 574 publications

Early Time Modifications to the Buoyancy-Drag Model for Richtmyer–Meshkov Mixing

Early Time Modifications to the Buoyancy-Drag Model for Richtmyer–Meshkov Mixing

Self-similar solutions of asymmetric Rayleigh-Taylor mixing

Buoyancy-Driven Instability and Growth

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