Why Shallow Water Slows Down Water Waves

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SUMMARY

Water waves travel more slowly in shallow water due to friction against the seabed and diffraction effects. In deep water, waves maintain higher amplitude and compactness, resulting in greater speed. The linear dispersion relation, defined by the equation c = √(g/k)√(tanh(kh)), indicates that phase velocity (c) increases with water depth (h). Additionally, amplitude dispersion shows that phase velocity also increases with wave amplitude, highlighting the complex relationship between speed, depth, and amplitude.

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why water wave travel more slowly in shallow water than deep water?
 
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Probably because of friction against the shallow ground.
 
Its probably because of the difraction of the wave. Off land, in deep water, the wave is more compact and has a higher amplitude. But once the wave gets to shalower water and moves inland, it diffracts, spreads out, and loses amplitude. This causes it to lose energy, and speed. It also could be because of friction.
 
What is the relationship between speed and amplitude?Is the formula Speed=wave length*frequency?
 
First of all, why does a given wave travel faster in deep water ?
To answer this sufficiently, we may regard the linear dispersion relation, which relates the wavenumber "k" with the phase velocity "c":
c=\sqrt{\frac{g}{k}}\sqrt{Tanh(kh)}
g is the acceleration of gravity, whereas "h" is the water depth.
Keeping the wavelength (and hence, k) constant and varying "h" we see that "c" increases with "h", having as maximum \sqrt{\frac{g}{k}}

Secondly, how does the phase velocity vary with the wave amplitude?
(This is called "amplitude dispersion")
This is a (stongly) non-linear effect, suffice it to say that the phase velocity increases with the amplitude.
 

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