Attracting Manifold for a Viscous Topology Transition

A. L. Bertozzi; A. Pumir; Adriana I. Pesci; B. I. Shraiman; D. W. Moore; G. Tryggvason; H. A. Stone; J. Eggers; J. Eggers; J. R. King; M. A. Lewis; M. C. Cross; M. D. Kruskal; M. P. Brenner; M. Tjahjadi; Michael J. Shelley; P. Constantin; P. Constantin; P. Constantin; R. E. Goldstein; R. E. Goldstein; Raymond E. Goldstein; S. Cardoso; S. H. Davis; S. Tanveer; T. F. Dupont; T. Y. Hou; W. Magnus; W. S. Rayleigh; X. D. Shi

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Attracting Manifold for a Viscous Topology Transition

Authors: A. L. Bertozzi
A. Pumir
Adriana I. Pesci
B. I. Shraiman
D. W. Moore
G. Tryggvason
H. A. Stone
J. Eggers
J. Eggers
J. R. King
M. A. Lewis
M. C. Cross
M. D. Kruskal
M. P. Brenner
M. Tjahjadi
Michael J. Shelley
P. Constantin
P. Constantin
P. Constantin
R. E. Goldstein
R. E. Goldstein
Raymond E. Goldstein
S. Cardoso
S. H. Davis
S. Tanveer
T. F. Dupont
T. Y. Hou
W. Magnus
W. S. Rayleigh
X. D. Shi
Publication date: 20 October 1995
Publisher: 'American Physical Society (APS)'
Doi

Abstract

An analytical method is developed describing the approach to a finite-time singularity associated with collapse of a narrow fluid layer in an unstable Hele-Shaw flow. Under the separation of time scales near a bifurcation point, a long-wavelength mode entrains higher-frequency modes, as described by a version of Hill's equation. In the slaved dynamics, the initial-value problem is solved explicitly, yielding the time and analytical structure of a singularity which is associated with the motion of zeroes in the complex plane. This suggests a general mechanism of singularity formation in this system.Comment: 4 pages, RevTeX, 3 ps figs included with text in uuencoded file, accepted in Phys. Rev. Let

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