The nonlinear states of viscous capillary jets confined in the axial direction

TL;DR

This study investigates how axial confinement affects the stability and nonlinear behavior of viscous liquid jets, revealing new regimes and stability boundaries through experiments and theoretical analysis.

Contribution

It provides the first detailed analysis of the impact of jet length on stability regimes, introducing a new oscillatory jetting state and mapping regime boundaries in the parameter space.

Findings

Q_c increases with jet length L, approaching a semi-infinite jet limit.

A new oscillatory jetting regime exists between steady jetting and dripping.

Regime boundaries depend on viscosity, flow rate Q, and injector radius R.

Abstract

We report an experimental and theoretical study of the global stability and nonlinear dynamics of vertical jets of viscous liquid confined in the axial direction due to their impact on a bath of the same liquid. Previous works demonstrated that in the absence of axial confinement the steady liquid thread becomes unstable due to an axisymmetric global mode for values of the flow rate, $Q$, below a certain critical value, $Q_c$, giving rise to oscillations of increasing amplitude that finally lead to a dripping regime (Sauter & Buggisch, J. Fluid Mech., 2005; Rubio-Rubio et al., J. Fluid Mech., 2013). Here we focus on the effect of the jet length, $L$, on the transitions that take place for decreasing values of $Q$. The linear stability analysis shows good agreement with our experiments, revealing that $Q_c$ increases monotonically with $L$, reaching the semi-infinite jet asymptote for large values of $L$. Moreover, as $L$ decreases a quasi-static limit is reached, whereby $Q_c \to 0$ and the neutral conditions are given by a critical length determined by hydrostatics. Our experiments have also revealed the existence of a new regime intermediate between steady jetting and dripping, in which the thread reaches a limit-cycle state without breakup. We thus show that there exist three possible states depending on the values of the control parameters, namely steady jetting, oscillatory jetting and dripping. For two different combinations of liquid viscosity, and injector radius, $R$, the boundaries separating these regimes have been determined in the $Q-L$ parameter plane, showing that steady jetting exists for small enough values of $L$ or large enough values of $Q$, dripping prevails for small enough values of $Q$ or sufficiently large values of $L$, and oscillatory jetting takes place in an intermediate region whose size increases with the liquid viscosity and decreases with $R$.