Mode coupling between two different interfaces of a gas layer subject to a shock

Chen, Chenren; Wang, He; Zhai, Zhigang; Luo, Xisheng

doi:10.1017/jfm.2024.232

J. Fluid Mech.

2024

DOI: 10.1017/jfm.2024.232

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Mode coupling between two different interfaces of a gas layer subject to a shock

Chenren Chen,

He Wang,

Zhigang Zhai

et al.

Abstract: Shock-tube experiments and theoretical studies have been performed to highlight mode-coupling in an air–SF $_6$ –air fluid layer. Initially, the two interfaces of the layer are designed as single mode with different basic modes. It is found that as the two perturbed interfaces become closer, interface coupling induces a different mode from the basic mode on each interface. Then mode coupling further generates new modes. Based on the linear model (Jacobs et al., J. Fluid Mech., vol. 29… Show more

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Cited by 2 publications

References 57 publications

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Effects of disturbed transmitted shock and interface coupling on heavy gas layer evolution

Chen,

Li,

Zhai

et al. 2024

Physics of Fluids

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Development of a heavy gas layer with an upstream single-mode interface and a downstream planar interface accelerated by a shock wave is investigated. By considering the amplitude variation of the transmitted shock and interface coupling, a modified model is established, which provides good predictions on the linear growth rates of the perturbations on both interfaces. Through the model, the perturbation growth of the downstream interface can be frozen by choosing a suitable layer width. In such a shocked layer, interface coupling has an ignorable effect on the nonlinear evolution of the upstream interface but significantly changes the nonlinear evolution of the downstream interface. A new dimensionless approach is proposed to scale the nonlinear growth of the middle spike on the downstream interface. Finally, through modal analysis, we find that the pressure perturbations rather than interface coupling result in the formation of the small spike on the bubble head of the downstream interface.

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Effects of disturbed transmitted shock and interface coupling on heavy gas layer evolution

Chen,

Li,

Zhai

et al. 2024

Physics of Fluids

View full text Add to dashboard Cite

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Simulations on perturbation growth and mixing of a shocked light fluid layer with two different interfaces

Zheng,

Guo,

Zhai

et al. 2024

Physics of Fluids

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The Richtmyer–Meshkov instability of a light fluid layer with two different interface modes is studied numerically. By fixing the wavelength of the second interface (I2) while varying that of the first interface (I1), we examine distinct cases with identical wavelengths at both interfaces, as well as smaller or larger wavelengths at I1, to explore the effects of initial layer configurations on instability development. The larger wavelength interface significantly transmits modes to the smaller wavelength interface, whereas mode transmission in the reverse direction is limited. This results in two primary consequences: (i) the smaller wavelength interface and the overall mixing layer evolve periodically with the larger wavelength; (ii) compared to the identical wavelength case, the linear amplitude growth duration of I2 is slightly extended for the smaller I1 wavelength case, but significantly prolonged for the larger I1 wavelength case. The linear amplitude growth rate of I2 for all cases can be predicted by the model of Jacobs et al. [J. Fluid Mech., vol. 195, 23–42 (1995)]. For cases with identical wavelengths and larger I1 wavelengths, the collisions of finger structures at both interfaces occur earlier, suppressing the growth of mixing width at early times while enhancing the mixed mass. In the later stages, the overall mixing efficiency in these cases significantly declines, despite continuous increases in both mixing width and mixed mass. This decline is attributed to severe deformation of the mixing layer due to interactions between finger structures, confining intense mixing to localized regions.

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Mode coupling between two different interfaces of a gas layer subject to a shock

Cited by 2 publications

References 57 publications

Effects of disturbed transmitted shock and interface coupling on heavy gas layer evolution

Effects of disturbed transmitted shock and interface coupling on heavy gas layer evolution

Simulations on perturbation growth and mixing of a shocked light fluid layer with two different interfaces

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