# Effect of viscosity ratio on the self-sustained instabilities in planar   immiscible jets

**Authors:** Outi Tammisola, Jean-Christophe Loiseau, Luca Brandt

arXiv: 1701.02972 · 2017-03-29

## TL;DR

This study investigates how viscosity ratio influences the stability and oscillatory behavior of planar immiscible jets using direct numerical simulation, revealing complex interactions between surface tension, viscosity, and flow instabilities.

## Contribution

It provides new insights into the destabilizing effects of viscosity ratio and surface tension on 2D immiscible jets, identifying different instability modes and their dependence on flow parameters.

## Key findings

- Persistent oscillations occur for all viscosity ratios studied.
- Surface tension-driven global instability initiates bifurcation at uniform viscosity.
- High viscosity outer fluid leads to convective instability and oscillations.

## Abstract

Previous studies have shown that intermediate surface tension has a counterintuitive destabilizing effect on 2-phase planar jets. Here, the transition process in confined 2D jets of two fluids with varying viscosity ratio is investigated using DNS. Neutral curves for persistent oscillations are found by recording the norm of the velocity residuals in DNS for over 1000 nondimensional time units, or until the signal has reached a constant level in a logarithmic scale - either a converged steady state, or a "statistically steady" oscillatory state. Oscillatory final states are found for all viscosity ratios (0.1-10). For uniform viscosity (m=1), the first bifurcation is through a surface tension-driven global instability. For low viscosity of the outer fluid, there is a mode competition between a steady asymmetric Coanda-type attachment mode and the surface tension-induced mode. At moderate surface tension, the Coanda-type attachment dominates and eventually triggers time-dependent convective bursts. At high surface tension, the surface tension-dominated mode dominates. For high viscosity of the outer fluid, persistent oscillations appear due to a strong convective instability. Finally, the m=1 jet remains unstable far from the inlet when the shear profile is nearly constant. Comparing this to a parallel Couette flow (without inflection points), we show that in both flows, a hidden interfacial mode brought out by surface tension becomes temporally and absolutely unstable in an intermediate Weber and Reynolds regime. An energy analysis of the Couette setup shows that surface tension, although dissipative, induces a velocity field near the interface which extracts energy from the flow through a viscous mechanism. This study highlights the rich dynamics of immiscible planar uniform-density jets, where several self-sustained and convective mechanisms compete depending on the exact parameters.

## Full text

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## Figures

34 figures with captions in the complete paper: https://tomesphere.com/paper/1701.02972/full.md

## References

25 references — full list in the complete paper: https://tomesphere.com/paper/1701.02972/full.md

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Source: https://tomesphere.com/paper/1701.02972