非线性系统
不稳定性
斜压性
物理
机械
涡度
经典力学
统计物理学
涡流
摄动(天文学)
指数函数
振幅
斯托克斯数
气泡
阻力
消散
流量(数学)
指数增长
多相流
流体静力平衡
Lift(数据挖掘)
时间演化
位涡度
压扁
Richtmyer-Meshkov不稳定性
动量(技术分析)
作者
Liu Lian,Baoqing Meng,Baolin Tian
标识
DOI:10.1017/jfm.2026.11484
摘要
This study develops a novel theoretical model for predicting the nonlinear evolution of Richtmyer–Meshkov instability (RMI) in particle-laden flows at large Stokes numbers. We construct a coupled multiphase potential flow theory framework incorporating two key models: (i) a postshock interface velocity attenuation model based on exponential decay accounting for momentum dissipation and (ii) a unified bubble and spike growth model for multiphase conditions. The multiphase-unified model maintains compatibility with classical single-phase RMI theories in the dilute limit, meanwhile revealing stronger particle-induced nonlinear decay in the amplitude growth rate. Model validation demonstrates good quantitative agreement across key predictive metrics – including dilute to dense particle volume fractions, Atwood numbers, particle sizes and initial perturbation amplitudes. This wide-range predictive capability for nonlinear instability growth may improve theoretical understanding of phenomena relevant to engineering applications. The results reveal that increased particle loading significantly reduces the growth rate of interface disturbances due to enhanced damping effects, leading to the blunting of spikes and flattening of bubbles. Vorticity dynamics analysis further shows that particle-induced vorticity weakens baroclinic production, thereby stabilizing the flow and inhibiting RMI development.
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