Transport between two fluids across their mutual flow interface: the streakline approach

TL;DR

This paper introduces a streakline-based theory to analyze and quantify the transport across the interface of two miscible fluids under unsteady velocity agitation, challenging traditional reliance on Lagrangian structures.

Contribution

It presents a novel streakline approach for understanding and locating the fluid transport interface, supported by simulations and a new quantification methodology.

Findings

Streaklines are crucial for understanding interface breaking.

Theoretical predictions match simulations in mixer and vortex scenarios.

A new method to quantify unsteady advective transport is proposed.

Abstract

Mixing between two different miscible fluids with a mutual interface must be initiated by fluid transporting across this fluid interface, caused for example by applying an unsteady velocity agitation. In general, there is no necessity for this physical flow barrier between the fluids to be associated with extremal or exponential attraction as might be revealed by applying Lagrangian coherent structures, finite-time Lyapunov exponents or other methods on the fluid velocity. It is shown that streaklines are key to understanding the breaking of the interface under velocity agitations, and a theory for locating the relevant streaklines is presented. Simulations of streaklines in a cross-channel mixer and a perturbed Kirchhoff's elliptic vortex are quantitatively compared to the theoretical results. A methodology for quantifying the unsteady advective transport between the two fluids using streaklines is presented.