Long-Wavelength Instability in Surface-Tension-Driven Benard Convection

A. Oron; A.A. Golovin; B.K. Kopbosynov; C. Pérez-García; D.A. Goussis; E.L. Koschmieder; H. Bénard; Harry L. Swinney; J. B. Swift; J.P. Burelbach; J.R.A. Pearson; K.A. Smith; L. Hadji; L.E. Scriven; M. Takashima; M.F. Schatz; M.F. Schatz; M.J. Block; Michael F. Schatz; P.L. Garcia-Ybarra; S.H. Davis; S.H. Davis; S.H. Davis; Stephen J. VanHook; William D. McCormick

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Long-Wavelength Instability in Surface-Tension-Driven Benard Convection

Authors: A. Oron
A.A. Golovin
B.K. Kopbosynov
C. Pérez-García
D.A. Goussis
E.L. Koschmieder
H. Bénard
Harry L. Swinney
J. B. Swift
J.P. Burelbach
J.R.A. Pearson
K.A. Smith
L. Hadji
L.E. Scriven
M. Takashima
M.F. Schatz
M.F. Schatz
M.J. Block
Michael F. Schatz
P.L. Garcia-Ybarra
S.H. Davis
S.H. Davis
S.H. Davis
Stephen J. VanHook
William D. McCormick
Publication date: 7 July 1995
Publisher: 'American Physical Society (APS)'
Doi

Abstract

Laboratory studies reveal a deformational instability that leads to a drained region (dry spot) in an initially flat liquid layer (with a free upper surface) heated uniformly from below. This long-wavelength instability supplants hexagonal convection cells as the primary instability in viscous liquid layers that are sufficiently thin or are in microgravity. The instability occurs at a temperature gradient 34% smaller than predicted by linear stability theory. Numerical simulations show a drained region qualitatively similar to that seen in the experiment.Comment: 4 pages. The RevTeX file has a macro allowing various styles. The appropriate style is "mypprint" which is the defaul

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