Richtmyer–Meshkov instability on a low Atwood number interface after reshock

Weber, Chris; Haehn, Nicholas; Oakley, Jason; Anderson, Mark; Bonazza, Riccardo

doi:10.1007/s00193-012-0367-x

Cited by 8 publications

(4 citation statements)

References 20 publications

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“…A reflected shock has generally been produced through an incident shock reflecting from a rigid wall (Weber et al. 2012; Jacobs et al. 2013; Mohaghar et al.…”

Section: Introductionmentioning

confidence: 99%

“…In experiments, two successive shock waves are difficult to generate in an ordinary shock tube and, therefore, experimental studies on freeze-out of a heavy-light interface perturbation are rare. A reflected shock has generally been produced through an incident shock reflecting from a rigid wall (Weber et al 2012;Jacobs et al 2013;Mohaghar et al 2019;Guo et al 2022). Such a reflected shock, however, is often too strong to realize freeze-out of a light-heavy perturbation.…”

Section: Introductionmentioning

confidence: 99%

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Freeze-out of perturbation growth of single-mode helium–air interface through reflected shock in Richtmyer–Meshkov flows

et al. 2023

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‘Freeze-out’ of amplitude growth, i.e. the amplitude growth stagnation of a shocked helium–air interface, is realized through a reflected shock, which produces baroclinic vorticity of the opposite sign to that deposited by the first shock. Theoretically, a model is constructed to calculate the relations among the initial parameters for achieving freeze-out. In particular, if the amplitude growth is within the linear regime at the arrival of the reflected shock, the time interval between the impacts of two shock waves is linearly related to the initial perturbation wavelength, and is independent of the initial perturbation amplitude. Experimentally, an air–SF $_6$ (or air–argon) plane interface is adopted to produce a weak reflected shock. Seven experimental runs with specific initial conditions are examined. For all cases, freeze-out is achieved after the reflected shock impact under the designed conditions.

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“…A reflected shock has generally been produced through an incident shock reflecting from a rigid wall (Weber et al. 2012; Jacobs et al. 2013; Mohaghar et al.…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Freeze-out of perturbation growth of single-mode helium–air interface through reflected shock in Richtmyer–Meshkov flows

et al. 2023

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“…In reshock experiments with initial single-mode (Collins & Jacobs 2002; Weber et al. 2012) or quasi-single-mode (Hahn et al. 2011; Mohaghar et al.…”

Section: Introductionmentioning

confidence: 99%

“…In these singly shocked experiments, the fundamental mode of quasi-single-mode interfaces was found to dominate the perturbation growth with similar evolutions of the single-mode interface. In reshock experiments with initial single-mode (Collins & Jacobs 2002;Weber et al 2012) or quasi-single-mode (Hahn et al 2011;Mohaghar et al 2017Mohaghar et al , 2019 interfaces, light/heavy configurations (the incident shock propagates from the light fluid to the heavy fluid) are often considered, while studies with heavy/light configurations (the incident shock propagates from the heavy fluid to the light fluid) seem to be rare (Hahn et al 2011). More importantly, most classical theories proposed for singly shocked cases (Richtmyer 1960;Sadot et al 1998;Dimonte & Ramaprabhu 2010;Zhang & Guo 2016) or reshock cases (Mikaelian 1989(Mikaelian , 2011(Mikaelian , 2015Charakhch'yan 2000) have been frequently tested in the experiments with an initial light/heavy interface (Vetter & Sturtevant 1995;Leinov et al 2009;Morgan et al 2012;Weber et al 2014;Mansoor et al 2020).…”

Section: Introductionmentioning

confidence: 99%

Shock-tube studies of single- and quasi-single-mode perturbation growth in Richtmyer–Meshkov flows with reshock

Cong

et al. 2022

J. Fluid Mech.

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The Richtmyer–Meshkov instability of heavy/light single-mode (SM), trapezoid (TR) and sawtooth (ST) interfaces is studied experimentally by considering the reshock. The TR and ST interfaces can be expanded into Fourier series with a dominant fundamental mode and more high-order modes, recognized as quasi-single-mode ones. In experiments, the distorted interfaces at the time of first reshock arrival develop in the weakly nonlinear stage, ensuring an approximate single-scale function of evolving interface. The results show an evident memory of initial interface shapes: the bubbles and spikes of ST interface after reshock mainly develop in the streamwise direction with sharp heads, while the counterparts of TR interface tend to grow in the spanwise direction. The influences of high-order modes are amplified by the reshock, resulting in significant interface shape dependence of mixing width growths. The amplitude superposition of major odd-order modes promotes the growth rates of mixing widths for the SM and ST cases, different from the TR one. The ST interface has larger mixing width growth rates in comparison with the SM interface, since high-order modes play a great role in promoting the increase of ST amplitudes, while the TR interface has a relatively small one. The linear and nonlinear mixing width growths of SM, TR and ST interfaces before and after reshock are further analysed theoretically, indicating that the fundamental mode still has a predominant influence on the interface evolution after reshock, and the growth behaviours exhibit strong similarities to those for the singly shocked cases.

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Research Activities at the Wisconsin Shock Tube Laboratory

Bonazza

2022

Frontiers of Shock Wave Research

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Richtmyer–Meshkov instability on a low Atwood number interface after reshock

Cited by 8 publications

References 20 publications

Freeze-out of perturbation growth of single-mode helium–air interface through reflected shock in Richtmyer–Meshkov flows

Freeze-out of perturbation growth of single-mode helium–air interface through reflected shock in Richtmyer–Meshkov flows

Shock-tube studies of single- and quasi-single-mode perturbation growth in Richtmyer–Meshkov flows with reshock

Research Activities at the Wisconsin Shock Tube Laboratory

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