Evolution of Rayleigh-Taylor turbulence under vorticity and strain-rate control

TL;DR

This paper explores how controlling high vorticity and strain-rate regions in Rayleigh-Taylor turbulence affects flow structures, mixing, and anisotropy, revealing that suppressing small-scale motions leads to more organized flows and reduced turbulence.

Contribution

It introduces a numerical flow control method targeting small-scale structures in RT turbulence and analyzes its effects on flow dynamics and turbulence characteristics.

Findings

Elimination of intense small-scale motions leads to more coherent structures.

Flow control reduces mixing and alters anisotropy.

Suppression of small-scale motions significantly diminishes turbulence.

Abstract

We investigate the role of small-scale structures in turbulent Rayleigh-Taylor (RT) flows through the application of preferential flow control targeting high vorticity or high strain-rate regions (Buzzicotti et al. 2020). Through numerical simulations, we analyze the effects of flow control on RT statistics, mixing, and anisotropy behavior. Our results reveal that eliminating intense small-scale motion leads to the formation of more organized and coherent flow structures, with reduced mixing and enhanced anisotropy. The alignment of vorticity and scalar gradient with the strain-rate eigen-frame is also altered by the flow control, reducing the downscale cascade of kinetic energy and the scalar variance. When the control threshold is set below the spatial mean of the vorticity or strain-rate field, turbulent motion in RT is significantly suppressed. Moreover, flow control eliminates regions of extreme vorticity and strain-rate, leading to overlapped high vorticity and high strain-rate regions with reduced turbulence intensity and more coherent structures. These findings provide a deeper understanding of the fundamental mechanisms played by small-scale structures in RT flows and their modulation through flow control. This work has broader implications for realistic scenarios, such as RT flows under magnetic fields or rotation, where suppression of small-scale motions plays a critical role.