Self-scalings of bubble pinch-off and inner jet emitting in a tapered co-flow

Abstract

This study systematically investigates the formation mechanisms and scaling laws governing sub-millimeter bubble-jet generation in convergent coaxial microchannels. Experimental observations reveal four distinct evolutionary stages in monodisperse bubble formation: growth, necking, detachment, and stabilization. Through necking rupture dynamics modeling, we demonstrate that the coupled effects of nozzle insertion length (x) and convergence angle (α) dominate neck width evolution, exhibiting universal power-law scaling across geometric configurations. Crucially, the spatiotemporal evolution of necking interfaces under shear demonstrates self-similarity: temporal evolution follows a power-law decay with respect to remaining time (T-t), while spatial scaling correlates with characteristic dimension Wlocal through power-law relationships. Multi-stage mathematical models successfully describe this self-similar interfacial behavior, confirming their predictive validity. Furthermore, we identify the core mechanism of bubble-jet formation as dynamic modulation through convergent zone flow fields characterized by front-end stretching and rear-end squeezing interactions. Experimental validation shows consistent jet velocity evolution across flow regimes under multiphysics coupling, establishing geometric similarity principles governing flow structures and dynamic behaviors in convergent microchannel architectures.