Everything about Tidal Resonance totally explained
In
oceanography, a
tidal resonance occurs when the
tide excites one of the resonant modes of the ocean. The effect is most striking when a
continental shelf is about a quarter wavelength wide. Then an incident tidal wave can be reinforced by reflections between the coast and the shelf edge, the result producing a much higher
tidal range at the coast.
Famous examples of this effect are found in the
Bay of Fundy, where the world's highest tides are reportedly found, and in the
Bristol Channel. Large tides due to resonances are also found on the Patagonian Shelf and on the N.W. Australian continental shelf.
The speed of long
waves in the ocean is given, to a good approximation, by
, where
g is the acceleration of gravity and
h is the depth of the ocean. For a typical continental shelf with a depth of 100 m, the speed is approximately 30 m/s. So if the tidal period is 12 hours, a quarter wavelength shelf will have a width of about 300 km.
With a narrower shelf, there's still a resonance but it has less effect at tidal frequencies. However the effect is still enough to help explain why tides along a coast lying behind a continental shelf are often higher than at offshore islands in the deep ocean. The strong tidal currents associated with resonances also mean that the resonant regions are the areas where most tidal energy is dissipated.
In the deep ocean, where the depth is typically 4000 m, the speed of long waves increases to approximately 200 m/s. The difference in speed, when compared to the shelf, is responsible for the reflections at the continental shelf edge. Away from resonance this can stop tidal energy moving onto the shelf. However near a resonant frequency the phase relationships between the wave on the shelf and in the deep ocean can have the effect of drawing energy onto the shelf.
The increased speed of long waves in the deep ocean means that the tidal wavelength there's of order 10,000 km. As the ocean basins have a similar size, they also have the potential of being resonant. In practice deep ocean resonances are difficult to observe, probably because the deep ocean loses tidal energy too rapidly to the resonant shelves.
Tidal locking
The above concept of tidal resonance differs from another sort of
resonance resulting from tides, called
tidal locking, which causes a
moon's rotational period to coincide with the period of its revolution around the planet that it orbits, so that one side of the moon always faces the planet.
Further Information
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