The primary instability of axisymmetric steady thermocapillary flow in a cylindrical liquid bridge with non-deformable free surface is calculated by a mixed Chebychev-finite difference method. For unit aspect ratio the most dangerous mode has an azimuthal wavenumber m=2. The physical instability mechanisms are studied by analyzing the linear energy balance of the neutral mode. If the Prandtl number is small (Pr≪1), the bifurcation is stationary. The associated neutral mode is amplified in the shear layer close to the free surface. For large Prandtl number (Pr=4), the basic state becomes linearly unstable to a pair of hydrothermal waves propagating nearly azimuthally. Both mechanisms are compared with those previously proposed in the literature.
The steady flow in rectangular cavities is investigated both numerically
and experimentally. The flow is driven by moving two facing walls tangentially
in
opposite
directions. It is found that the basic two-dimensional flow is not always
unique. For
low Reynolds numbers it consists of two separate co-rotating vortices adjacent
to the
moving walls. If the difference in the sidewall Reynolds numbers is large
this flow
becomes unstable to a stationary three-dimensional mode with a long wavelength.
When the aspect ratio is larger than two and both Reynolds numbers are
large, but
comparable in magnitude, a second two-dimensional flow exists. It takes
the form
of a single vortex occupying the whole cavity. This flow is the preferred
state
in the
present experiment. It becomes unstable to a three-dimensional mode that
subdivides
the basic streched vortex flow into rectangular convective cells. The instability
is
supercritical when both sidewall Reynolds numbers are the same. When they
differ
the instability is subcritical. From an energy analysis and from the salient
features
of the three-dimensional flow it is concluded that the mechanism of destabilization
is identical to the destabilization mechanism operative in the elliptical
instability of highly strained vortices.
The stability of steady axisymmetric convection in cylinders heated from below and insulated laterally is investigated numerically using a mixed finite-difference/Chebyshev collocation method to solve the base flow and the linear stability equations. Linear stability boundaries are given for radius to height ratios γ from 0.9 to 1.56 and for Prandtl numbers Pr = 0.02 and Pr = 1. Depending on γ and Pr, the azimuthal wavenumber of the critical mode may be m = 1, 2, 3, or 4. The dependence of the critical Rayleigh number on the aspect ratio and the instability mechanisms are explained by analysing the energy transfer to the critical modes for selected cases. In addition to these results the onset of buoyant convection in liquid bridges with stress-free conditions on the cylindrical surface is considered. For insulating thermal boundary conditions, the onset of convection is never axisymmetric and the critical azimuthal wavenumber increases monotonically with γ. The critical Rayleigh number is less then 1708 for most aspect ratios.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.