Single-Mode Richtmyer–Meshkov Instability in Light Fluid Layer: Insights from Numerical Simulations

Single-Mode Richtmyer–Meshkov Instability in Light Fluid Layer: Insights from Numerical Simulations

This study presents high-fidelity numerical simulations of the shock-accelerated single-mode Richtmyer–Meshkov instability (RMI) in a light helium layer confined between two interfaces and surrounded by nitrogen gas. A high-order modal discontinuous Galerkin method is employed to solve the two-dimen...

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Bibliographic Details
Main Authors: Ahmed Hussein Msmali, Satyvir Singh, Mutum Zico Meetei
Format: Article
Language:English
Published: MDPI AG 2025-06-01
Series:Axioms
Subjects:
Richtmyer–Meshkov instability
shock-accelerated interface
light fluid layer
baroclinic vorticity generation
discontinuous Galerkin method
Online Access:https://www.mdpi.com/2075-1680/14/6/473
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Summary:This study presents high-fidelity numerical simulations of the shock-accelerated single-mode Richtmyer–Meshkov instability (RMI) in a light helium layer confined between two interfaces and surrounded by nitrogen gas. A high-order modal discontinuous Galerkin method is employed to solve the two-dimensional compressible Euler equations, enabling detailed investigation of interface evolution, vorticity dynamics, and flow structure development under various physical conditions. The effects of helium layer thickness, initial perturbation amplitude, and incident shock Mach number are systematically explored by analyzing interface morphology, vorticity generation, enstrophy, and kinetic energy. The results show that increasing the helium layer thickness enhances vorticity accumulation and interface deformation by delaying interaction with the second interface, allowing more sustained instability growth. Larger initial perturbation amplitudes promote earlier onset of nonlinear deformation and stronger baroclinic vorticity generation, while higher shock strengths intensify pressure gradients across the interface, accelerating instability amplification and mixing. These findings highlight the critical interplay between layer confinement, perturbation strength, and shock strength in governing the nonlinear evolution of RMI in light fluid layers.
ISSN:2075-1680

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