Scale-dependent Rayleigh-Taylor dynamics with variable acceleration by group theory approach

TL;DR

This paper develops a unified, group theory-based framework to analyze the scale-dependent dynamics of Rayleigh-Taylor instability driven by variable acceleration, covering linear and nonlinear regimes with detailed solutions and stability analysis.

Contribution

It introduces a novel group theory approach to unify the understanding of RTI dynamics across scales and regimes, including solutions for bubbles and spikes, and stability properties.

Findings

Fastest Atwood bubble is stable and regular.

Fastest Atwood spike is unstable and singular.

Theory aligns with experimental observations.

Abstract

This work focuses on Rayleigh-Taylor instability (RTI)driven by acceleration with power-law time-dependence. We review the existing theoretical approaches, apply the group theory approach to solve this long-standing problem, and yield the unified framework for the scale-dependent dynamics of Rayleigh-Taylor (RT) bubbles and RT spikes. For the early-time linear dynamics we provide the dependence of RTI evolution on the acceleration parameters and the initial conditions. For the late-time nonlinear dynamics, we find a continuous family of asymptotic solutions, directly link the interface velocity to the interface morphology and the interfacial shear, derive solutions for the regular bubbles and for the singular spikes, and study stability of these solutions. The properties of special nonlinear solutions in the RT family are scrupulously described, including the critical, the Taylor, the Layzer-drag, and the Atwood solutions. It is shown that the fastest Atwood bubble is regular and stable, and the fastest Atwood spike is singular and unstable. The essentially multi-scale and interfacial character of RT dynamics is demonstrated. The former can be understood by viewing RT coherent structure of bubbles and spikes as a standing wave with the growing amplitude. The latter implies that RT flow has effectively no motion of the fluids away from the interface and has intense motion of the fluids near the interface, with shear-driven vortical structures appearing at the interface. Our theory agrees with available observations, and elaborates extensive benchmarks for future research and for better understanding of RT driven phenomena in plasmas.