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Convergent Richtmyer–Meshkov turbulence by time-resolved planar laser-induced fluorescence measurement

Yong Zhao, Juchun Ding, Dong He, Zhangbo Zhou, Xisheng Luo

2025Journal of Fluid Mechanics7 citationsDOIOpen Access PDF

Abstract

We report the first measurement of turbulent mixing developing from the convergent Richtmyer–Meshkov (RM) instability using time-resolved planar laser-induced fluorescence in a semi-annular convergent shock tube. A membraneless yet sharp interface with random short-wavelength perturbations, but controllable long-wavelength perturbations, is created by an automatically retractable plate, enhancing the reproducibility and reliability of RM turbulence experiments. The cylindrical air/SF $_6$ interface formed is first subjected to a convergent shock, then to its reflected shock and subsequently transits to turbulent mixing. It is found that the mixing width after reshock has a linear growth rate more than twice the rate in planar geometry. Also, the mixing width does not present power-law growth at late stages as in a planar geometry. However, the scalar spectrum and transition criterion obtained are similar to their planar counterparts. These findings indicate that the geometric constraint greatly affects the large scales of the flow, while having a weaker effect on the small scales. It is also found that the reflected shock significantly increases both scale separation and Reynolds number, explaining the rapid transition to turbulence following reshock.

Topics & Concepts

TurbulenceRichtmyer–Meshkov instabilityPlanarPlanar laser-induced fluorescenceMechanicsOpticsPhysicsMaterials scienceLaserLaser-induced fluorescenceComputer scienceShock waveComputer graphics (images)Laser-Plasma Interactions and DiagnosticsFluid Dynamics and Turbulent FlowsLaser-Matter Interactions and Applications
Convergent Richtmyer–Meshkov turbulence by time-resolved planar laser-induced fluorescence measurement | Litcius