Abstract
In hydrodynamic topological transitions, one mass of fluid breaks into two or two merge into one. For example, in the honey-drop formation when honey dripping from a spoon, honey is extended to separate into two as the liquid neck bridging them thins down to micron scales. At the moment when topology changes due to the breakup, physical observables such as surface curvature locally diverges. Such singular dynamics have widely attracted physicists, revealing universality in their self-similar dynamics, which share much in common with critical phenomena in thermodynamics. Many experimental examples have been found, which include electric spout and vibration-induced jet eruption. However, only a few cases have been physically understood on the basis of equations that govern the singular dynamics and even in such a case the physical understanding is mathematically complicated inevitably involving delicate numerical calculations. Here, we study breakup of air film entrained by a solid disk into viscous liquid in a confined space, which leads to formation, thinning and breakup of the neck of air. As a result, we unexpectedly find that equations governing the neck dynamics can be solved analytically by virtue of two remarkable experimental features: only a single length scale linearly dependent on time remains near the singularity and universal scaling functions describing singular neck shape and velocity field are both analytic. The present solvable case would be essential for our better understanding of the singular dynamics and will help unveil the physics of unresolved examples intimately related to daily-life phenomena and diverse practical applications.
Highlights
The self-similar dynamics in hydrodynamics was already in focus when the dynamics of viscous instability of a moving front was studied [1] and the renormalization group theory in statistical physics, which elucidates universality appearing in critical phenomena in thermodynamics, was recognized worldwide beyond fields [2]
Most of previous experimental examples possess more than one remaining length scales near the singularity and at least one of the universal scaling functions is nonanalytic
The air is dragged by the disk as in Fig. 1(c), forming a singular shape, with details revealed in Figs. 2(a) and 2(b), and pinches off to cause a topological transition
Summary
The self-similar dynamics in hydrodynamics was already in focus when the dynamics of viscous instability of a moving front was studied [1] and the renormalization group theory in statistical physics, which elucidates universality appearing in critical phenomena in thermodynamics, was recognized worldwide beyond fields [2]. Most of previous experimental examples possess more than one remaining length scales near the singularity and at least one of the universal scaling functions is nonanalytic This is the case for well-understood cases [7] such as the pioneering study associated with the Hele-Shaw cell [3] [see just below Eq (7)] and another seemingly similar case of the flow-induced air entrainment [27,29] (see Sec. III for details). The present study advances our general understanding of the singular dynamics; it represents an important fundamental example of the singular dynamics, providing insight into unresolved self-similar dynamics such as the electric spout of liquid [24], the selective withdrawal [30], and the electric-field-induced drop coalescence [26], and impacting the study of the dynamics of droplets and bubbles in general.
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