Late-time turbulent mixing induced by multimode Richtmyer–Meshkov instability in cylindrical geometry

Ge, Jin; Zhang, Xinting; Li, Haifeng; Tian, Buning

doi:10.1063/5.0035603

Cited by 6 publications

(14 citation statements)

References 67 publications

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“…2021) and convergent geometry (Ge et al. 2020) on the evolution of RM instability. For completeness, we give a brief derivation of the S(C) effect.…”

Section: Theoretical Analysis On the S(c) Effectmentioning

confidence: 99%

“…However, in the convergent geometry, the S(C) effect is evident even when there is no wave in the mixing zone (Ge et al. 2020). Therefore, the S(C) effect is an important difference between the interfacial mixing in planar geometry and that in convergent geometry.…”

Section: Theoretical Analysis On the S(c) Effectmentioning

confidence: 99%

“…More recently, Ge et al. (2020) carried out three-dimensional simulations of cylindrical RM instability. As a result, a stretching effect exists obviously in cylindrical geometry.…”

Section: Introductionmentioning

confidence: 99%

“…Ge et al. (2020) ascribe this stretching effect in cylindrical geometry to ‘an asymmetric geometric environment’. However, there is no detailed explanation of this asymmetric geometric environment.…”

Section: Introductionmentioning

confidence: 99%

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Evaluating the stretching/compression effect of Richtmyer–Meshkov instability in convergent geometries

Zhang

et al. 2022

J. Fluid Mech.

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Richtmyer–Meshkov (RM) instability in convergent geometries (such as cylinders and spheres) plays a fundamental role in natural phenomena and engineering applications, e.g. supernova explosion and inertial confinement fusion. Convergent geometry refers to a system in which the interface converges and the fluids are compressed correspondingly. By applying a decomposition formula, the stretching or compression (S(C)) effect is separated from the perturbation growth as one of the main contributions, which is defined as the averaged velocity difference between two ends of the mixing zone. Starting from linear theories, the S(C) effect in planar, cylindrical and spherical geometries is derived as a function of geometrical convergence ratio, compression ratio and mixing width. Specifically, geometrical convergence stretches the mixing zone, while fluid compression compresses the mixing zone. Moreover, the contribution of geometrical convergence in the spherical geometry is more important than that in the cylindrical geometry. A series of cylindrical cases with high convergence ratio is simulated, and the growth of perturbations is compared with that of the corresponding planar cases. As a result, the theoretical results of the S(C) effect agree well with the numerical results. Furthermore, results show that the S(C) effect is a significant feature in convergent geometries. Therefore, the S(C) effect is an important part of the Bell–Plesset effect. The present work on the S(C) effect is important for further modelling of the mixing width of convergent RM instabilities.

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“…2021) and convergent geometry (Ge et al. 2020) on the evolution of RM instability. For completeness, we give a brief derivation of the S(C) effect.…”

Section: Theoretical Analysis On the S(c) Effectmentioning

confidence: 99%

Section: Theoretical Analysis On the S(c) Effectmentioning

confidence: 99%

“…More recently, Ge et al. (2020) carried out three-dimensional simulations of cylindrical RM instability. As a result, a stretching effect exists obviously in cylindrical geometry.…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Evaluating the stretching/compression effect of Richtmyer–Meshkov instability in convergent geometries

Zhang

et al. 2022

J. Fluid Mech.

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“…As the research progresses, the problem being studied and the models being used are becoming more and more practical and complex [8][9][10][11][12][13][14][15][16][17][18][19][20][21]. In recent years, the results in statistical physics perspectives obtained with the help of Discrete Boltzmann Method (DBM) and complex physical field analysis techniques have also provided a range of new insights into the study of hydrodynamic instabilities.…”

Section: Introductionmentioning

confidence: 99%

Discrete Boltzmann modeling of Rayleigh-Taylor instability: effects of interfacial tension, viscosity and heat conductivity

Chen,

Xu,

Chen

et al. 2022

Preprint

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The Rayleigh-Taylor Instability (RTI) in compressible flow with inter-molecular interactions is probed via the Discrete Boltzmann Method (DBM). The effects of interfacial tension, viscosity and heat conduction are investigated. It is found that the influences of interfacial tension on the perturbation amplitude, bubble velocity, and two kinds of entropy production rates all show differences at different stages of RTI evolution. It inhibits the RTI evolution at the bubble acceleration stage, while at the asymptotic velocity stage, it first promotes and then inhibits the RTI evolution.Viscosity and heat conduction inhibit the RTI evolution. Viscosity shows a suppressive effect on entropy generation rate related to heat flow at the early stage but a first promotive and then suppressive effect on entropy generation rate related to heat flow at a later stage. Heat conduction shows a promotive effect on entropy generation rate related to heat flow at an early stage. Still, it offers a first promotive and then suppressive effect on entropy generation rate related to heat flow at a later stage. By introducing the morphological boundary length, we found that the stage of exponential growth of interface length with time corresponds to the bubble acceleration stage. The first maximum point of interface length change rate and the first maximum point of the change rate of entropy generation rate related to viscous stress can be used as a new criterion for RTI to enter the asymptotic velocity stage.

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Instability evolution of a shock-accelerated thin heavy fluid layer in cylindrical geometry

et al. 2023

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Instability evolutions of shock-accelerated thin cylindrical SF $_6$ layers surrounded by air with initial perturbations imposed only at the outer interface (i.e. the ‘Outer’ case) or at the inner interface (i.e. the ‘Inner’ case) are numerically and theoretically investigated. It is found that the instability evolution of a thin cylindrical heavy fluid layer not only involves the effects of Richtmyer–Meshkov instability, Rayleigh–Taylor stability/instability and compressibility coupled with the Bell–Plesset effect, which determine the instability evolution of the single cylindrical interface, but also strongly depends on the waves reverberated inside the layer, thin-shell correction and interface coupling effect. Specifically, the rarefaction wave inside the thin fluid layer accelerates the outer interface inward and induces the decompression effect for both the Outer and Inner cases, and the compression wave inside the fluid layer accelerates the inner interface inward and causes the decompression effect for the Outer case and compression effect for the Inner case. It is noted that the compressible Bell model excluding the compression/decompression effect of waves, thin-shell correction and interface coupling effect deviates significantly from the perturbation growth. To this end, an improved compressible Bell model is proposed, including three new terms to quantify the compression/decompression effect of waves, thin-shell correction and interface coupling effect, respectively. This improved model is verified by numerical results and successfully characterizes various effects that contribute to the perturbation growth of a shock-accelerated thin heavy fluid layer.

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Late-time turbulent mixing induced by multimode Richtmyer–Meshkov instability in cylindrical geometry

Cited by 6 publications

References 67 publications

Evaluating the stretching/compression effect of Richtmyer–Meshkov instability in convergent geometries

Evaluating the stretching/compression effect of Richtmyer–Meshkov instability in convergent geometries

Discrete Boltzmann modeling of Rayleigh-Taylor instability: effects of interfacial tension, viscosity and heat conductivity

Instability evolution of a shock-accelerated thin heavy fluid layer in cylindrical geometry

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