Richtmyer–Meshkov instability at high Mach number: Non-Newtonian effects

• Published in: Physics of fluids (1994) Vol. 36; no. 6
• Main Authors: Rana, U., Abadie, T., Chapman, D., Joiner, N., Matar, O. K.
• Format: Journal Article
• Language: English
• Published: Melville American Institute of Physics 01.06.2024
• Subjects: Damping; High Mach number; Inertial confinement fusion; Interface stability; Numerical models; Richtmeyer-Meshkov instability; Shear thinning (liquids); Supersonic combustion; Vorticity
• ISSN: 1070-6631; 1089-7666
• DOI: 10.1063/5.0209843

The Richtmyer–Meshkov instability (RMI) occurs when a shock wave passes through an interface between fluids of different densities, a phenomenon prevalent in a variety of scenarios including supersonic combustion, supernovae, and inertial confinement fusion. In the most advanced current numerical modeling of RMI, a multitude of secondary physical phenomena are typically neglected that may crucially change in silico predictions. In this study, we investigate the effects of shear-thinning behavior of a fluid on the RMI at negative Atwood numbers via numerical simulations. A parametric study is carried out over a wide range of Atwood and Mach numbers that probes the flow dynamics following the impact on the interface of the initial shock wave and subsequent, reflected shocks. We demonstrate agreement between our numerical results and analytical predictions, which are valid during the early stages of the flow, and examine the effect of the system parameters on the vorticity distribution near the interface. We also carry out an analysis of the rate of vorticity production and dissipation budget which pinpoints the physical mechanisms leading to instability due to the initial and reflected shocks. Our findings indicate that the shear-thinning effects have a significant impact on instability growth and the development of secondary instabilities, which manifest themselves through the formation of Kelvin–Helmholtz waves. Specifically, we demonstrate that these effects influence vorticity generation and damping, which, in turn, affect the RMI growth. These insights have important implications for a range of applications, including inertial confinement fusion and bubble collapse within non-Newtonian materials.