2009 APS March Meeting
Volume 54, Number 1
Monday–Friday, March 16–20, 2009;
Pittsburgh, Pennsylvania
Session Q1: Memory and Focusing in Catastrophic Deformations
11:15 AM–1:39 PM,
Wednesday, March 18, 2009
Room: Spirit of Pittsburgh Ballroom A
Sponsoring
Unit:
DCMP
Chair: Michael Brenner, Harvard University
Abstract ID: BAPS.2009.MAR.Q1.2
Abstract: Q1.00002 : Memory encoding vibrations in a disconnecting air bubble
11:51 AM–12:27 PM
Preview Abstract
Abstract
Author:
Wendy Zhang
(University of Chicago)
The implosion that disconnects a submerged air bubble into
several bubbles provides a simple example of energy focusing.
The most efficient disconnection is an entirely symmetric one
terminating in a finite-time singularity. At the final moment,
the potential energy at the start of the disconnection is
entirely condensed into the kinetic energy of a vanishingly small
amount of liquid rushing inwards to disconnect the bubble. In
reality, however, the initial shape always possesses slight
imperfections. We show that a memory of the imperfection remains
and controls the final fate of the focusing.
Linear stability reveals that even an infinitesimal perturbation
is remembered. A slight initial asymmetry excites vibrations in
the cross-section shape of the bubble neck. The vibrations
persist over time. Near the singularity, their amplitudes
freeze, locking onto constant values, while their frequencies
chirp, increasing more and more rapidly. The net effect is that
the singularity remembers exactly half of the information about
the initial imperfection, the half encoded by the vibration
amplitudes. We check this scenario in an experiment by releasing
an air bubble from a nozzle with an oblong cross-section. This
excites an elongation-compression vibrational mode. We measure
the vibration excited and find quantitative agreement with linear
stability.
When the initial distortion has a small, but finite, size, the
saturation of the vibration amplitude causes the symmetric
singularity to be pre-empted by an asymmetric contact between two
distant points on the interface. Numerics reveal that the contact
is typically smooth, corresponding to two inward-curving portions
of the bubble surface colliding at finite speed. Both the
contact speed and curvature vary non-monotonically with the
initial distortion size, with abrupt jumps at specific values.
This is because the vibration causes contact to occur at
different values of the phase. A contact produced when the shape
distortion is pronounced requires a smaller initial amplitude
than a contact produced when the vibration is out of phase.
(Joint work with Nathan C. Keim, Lipeng Lai, Laura E. Schmidt,
Konstantin Turitsyn and Sidney R. Nagel.)
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2009.MAR.Q1.2