Kelvin–Helmholtz instability

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The Kelvin–Helmholtz instability (after Lord Kelvin and Hermann von Helmholtz) can occur when there is velocity shear in a single continuous fluid, or where there is a velocity difference across the interface between two fluids. An example is wind blowing over water: The instability manifests in waves on the water surface. More generally, clouds, the ocean, Saturn's bands, Jupiter's Red Spot, and the sun's corona show this instability.^[1]

The theory predicts the onset of instability and transition to turbulent flow in fluids of different densities moving at various speeds. Helmholtz studied the dynamics of two fluids of different densities when a small disturbance, such as a wave, was introduced at the boundary connecting the fluids.

A KH instability rendered visible by clouds over Mount Duval in Australia

For some short enough wavelengths, if surface tension is ignored, two fluids in parallel motion with different velocities and densities yield an interface that is unstable for all speeds. Surface tension stabilises the short wavelength instability however, and theory predicts stability until a velocity threshold is reached. The theory, with surface tension included, broadly predicts the onset of wave formation in the important case of wind over water.^{[citation needed]}

A KH instability on the planet Saturn, formed at the interaction of two bands of the planet's atmosphere

Kelvin-Helmholtz billows 500m deep in the Atlantic Ocean

For a continuously varying distribution of density and velocity (with the lighter layers uppermost, so that the fluid is RT-stable), the dynamics of the KH instability is described by the Taylor–Goldstein equation and its onset is given by a Richardson number, Ri. Typically the layer is unstable for Ri<0.25. These effects are common in cloud layers. The study of this instability is applicable in plasma physics, for example in inertial confinement fusion and the plasma–beryllium interface.

Numerically, the KH instability is simulated in a temporal or a spatial approach. In the temporal approach, experimenters consider the flow in a periodic (cyclic) box "moving" at mean speed (absolute instability). In the spatial approach, experimenters simulate a lab experiment with natural inlet and outlet conditions (convective instability).

See also

• Rayleigh–Taylor instability
• Richtmyer–Meshkov instability
• Mushroom cloud
• Plateau–Rayleigh instability
• Kármán vortex street
• Taylor–Couette flow
• Fluid mechanics
• Fluid dynamics

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Notes

References

Wikimedia Commons has media related to Kelvin-Helmholtz waves.

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• Article describing discovery of K-H waves in deep ocean: Lua error in package.lua at line 80: module 'strict' not found.

External links

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• Giant Tsunami-Shaped Clouds Roll Across Alabama Sky - Natalie Wolchover, Livescience via Yahoo.com
• Tsunami Cloud Hits Florida Coastline
• Vortex formation in free jet - YouTube video showing Kelvin Helmholtz waves on the edge of a free jet visualised in a scientific experiment.