A Sverdrup wave (also known as Poincaré wave, or rotational gravity wave Kundu, P. K., and L. M. Cohen. "Fluid mechanics, 638 pp." Academic, Calif (1990).) is a wave in the ocean, or large lakes, which is affected by gravity and Earth's rotation (see

Coriolis effect In physics, the Coriolis force is an inertial or fictitious force that acts on objects in motion within a frame of reference that rotates with respect to an inertial frame. In a reference frame with clockwise rotation, the force acts to the ...

). For a non-rotating fluid, shallow water waves are affected only by gravity (see

Gravity wave In fluid dynamics, gravity waves are waves generated in a fluid medium or at the interface between two media when the force of gravity or buoyancy tries to restore equilibrium. An example of such an interface is that between the atmosphere ...

), where the

phase velocity The phase velocity of a wave is the rate at which the wave propagates in any medium. This is the velocity at which the phase of any one frequency component of the wave travels. For such a component, any given phase of the wave (for example, ...

of shallow water gravity wave (''c'') can be noted as :

c = (gH)^

and the group velocity (''c''_g) of shallow water gravity wave can be noted as :

c_\mathrm=(gH)^

i.e.

c=c_\mathrm

where ''g'' is gravity, ''λ'' is the

wavelength In physics, the wavelength is the spatial period of a periodic wave—the distance over which the wave's shape repeats. It is the distance between consecutive corresponding points of the same phase on the wave, such as two adjacent crests, tro ...

and ''H'' is the total depth.

Derivation

When the fluid is rotating, gravity waves with a long enough wavelength (discussed below) will also be affected by rotational forces. The linearized, shallow-water equations with a constant rotation rate, ''f₀'', are Vallis, Geoffrey K. Atmospheric and oceanic fluid dynamics: fundamentals and large-scale circulation. Cambridge University Press, 2006. :

\frac - f_0v = -g\frac,

\frac + f_0u = -g\frac,

\frac + H(u_x+v_y) = 0,

where ''u'' and ''v'' are the horizontal velocities and ''h'' is the instantaneous height of the free surface. Using Fourier analysis, these equations can be combined to find the

dispersion relation In the physical sciences and electrical engineering, dispersion relations describe the effect of dispersion on the properties of waves in a medium. A dispersion relation relates the wavelength or wavenumber of a wave to its frequency. Given the d ...

for Sverdrup waves: :

\omega^2 = f_0^2 + gH(k^2 + l^2),

where ''k'' and ''l'' are the wavenumbers associated with the horizontal and vertical directions, and

\omega

is the frequency of oscillation.

Limiting Cases

There are two primary modes of interest when considering Poincaré waves: * Short wave limit

(k^2 + l^2) \gg \frac \qquad \textrm \qquad (k^2+l^2) \gg L_D^,

where

L_D  = \frac

is the

Rossby radius of deformation In atmospheric dynamics and physical oceanography, the Rossby radius of deformation is the length scale at which rotational effects become as important as buoyancy or gravity wave effects in the evolution of the flow about some disturbance. Fo ...

. In this limit, the dispersion relation reduces to the solution for a non-rotating gravity wave. * Long wave limit

(k^2 + l^2) \ll \frac \qquad \textrm \qquad (k^2+l^2) \ll L_D^,

which looks like inertial oscillations driven purely by rotational forces.

Solution for the one-dimensional case

For a wave traveling in one direction (

l = 0

), the horizontal velocities are found to be equal to :

u = \frac H_0\cos(kx-\omega t)

v = \frac{kH} H_0\sin(kx-\omega t).

This shows that the inclusion of rotation will cause the wave to develop oscillations at 90° to the wave propagation at the opposite phase. In general, these are elliptical orbits that depend on the relative strength of gravity and rotation. In the long wave limit, these are circular orbits characterized by inertial oscillations.

Derivation

Limiting Cases

Solution for the one-dimensional case

References

See also