arXiv:physics/0111003 Abstract

arXiv:physics/0111003 [physics.flu-dyn]Abstract References Reviews Resources

Theory of Drop Formation

Published 2001-11-02Version 1

We consider the motion of an axisymmetric column of Navier-Stokes fluid with a free surface. Due to surface tension, the thickness of the fluid neck goes to zero in finite time. After the singularity, the fluid consists of two halves, which constitute a unique continuation of the Navier-Stokes equation through the singular point. We calculate the asymptotic solutions of the Navier-Stokes equation, both before and after the singularity. The solutions have scaling form, characterized by universal exponents as well as universal scaling functions, which we compute without adjustable parameters.

Journal: Physics of Fluids 7, 941-953 (1994)

DOI: 10.1063/1.868570

Categories: physics.flu-dyn

Keywords: drop formation, navier-stokes equation, fluid consists, navier-stokes fluid, universal scaling functions

Tags: journal article

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Theory of Drop Formation

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Theory of Drop Formation

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arXiv:physics/0111003 [physics.flu-dyn]Abstract References Reviews Resources