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

Harry L. Swinney (Center for Nonlinear Dynamics; J. B. Swift; Michael F. Schatz; Stephen J. Vanhook; University of Texas at Austin); William D. McCormick

arxiv: patt-sol/9507001 · v1 · submitted 1995-07-07 · patt-sol · nlin.PS

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

Stephen J. Vanhook , Michael F. Schatz , William D. McCormick , J. B. Swift , Harry L. Swinney (Center for Nonlinear Dynamics , University of Texas at Austin) This is my paper

classification patt-sol nlin.PS

keywords instabilityconvectiondrainedliquidlong-wavelengthregionbelowbenard

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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.

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

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