Tsunami Waves & Mechanical Wave Physics

In summary, the energy of a tsunami wave, as described in bullet (4) of the conversation, is not proportional to the square of the amplitude of the wave. It is instead proportional to the volume of water displaced by the crest and trough of the wave. This volume is still very large, even though the amplitude is small, because the wavelength is very long. As the tsunami wave approaches shallow water, equation [2] would restrict the propagation velocity is a function of the depth of the water, not its wavelength. Does the amplitude of the wave grow to compensate, i.e. is this some form of conservation of energy? While I assume that some wave energy must be lost to friction in shallow water, is it correct to
  • #1
mysearch
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Hi,
I was wondering if anybody is in a position to resolve some questions about tsunami waves as they relate to the general physics of mechanical waves. I will briefly try to outline the issues:

1. The energy of a mechanical wave, i.e. one dependent on the physical interaction of the particles in the propagating medium is normally said to be proportional to the square of the amplitude of the wave.

2. Wikipedia has a page on ocean waves that gives a generalised solution of a wave’s propagation velocity: http://en.wikipedia.org/wiki/Ocean_surface_wave. However, this solution can be simplified for discussion by considering the following deep and shallow depth solutions:

[1] [tex]v = \sqrt { \frac {g\lambda}{2 \pi} } [/tex] deep water

[2] [tex]v = \sqrt { gd} [/tex] shallow water

3. Now descriptions of tsunami waves suggest that the amplitude of the wave is relatively small, e.g. 1 metre, but the wavelength is very long, e.g. 10-100km, in deep water. As such, equation [1] would suggest that these waves also move very fast.

4. However, if tsunami waves are classified as mechanical waves, they seem to conflict with the energy of the wave being proportional to the square of the amplitude.​

I have some thoughts of why this might be the case, but would like to get some general feedback on the specific issue associated with energy in bullet (4) above:

5. At some level, the energy of the wave seems to be related to the volume of water displaced by the crest and trough of the wave. In the case of tsunami waves, the energy-volume is still very large, even though the amplitude is small, because the wavelength is so long.

6. As the tsunami wave approaches shallow water, equation [2] would restrict the propagation velocity is a function of the depth of the water, not its wavelength.

7. Does the amplitude of the wave grow to compensate, i.e. is this some form of conservation of energy?

8. While I assume that some wave energy must be lost to friction in shallow water, is it correct to assume, in this specific case, that the wave energy is still characterised by the volume of water displaced, i.e. is this representative of potential energy?

9. Finally, does the propagation velocity of a mechanical wave reflect some sort of notion of the kinetic energy associated with the wave? I am asking this question because a SHM wave model cycles between potential and kinetic energy maxima​
Would appreciate any clarification of any of the issues raised. Thanks
 
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  • #2
By way of an addendum to my original post, I am trying to consider a tsunami wave in the context of a 2-dimensional surface wave model, which radiates outwards from some central event. Clearly, this event has to inject the necessary energy into the system to trigger the wave in the first place, e.g.

o Seismic event, ocean floor sinks
o Meteor strike

Is correct to assume that some portion of the energy of the originating event is transported away in the form of the tsunami wave, analogous to a large pebble in a large pond?

Now, in the pebble model, the initial energy is also being distributed over an ever-increasing circumference, such that the amplitude at any point is proportional to:

[1] [tex] A \propto \frac{1}{\sqrt{radius}}[/tex]

However, the issue of interest is whether a tsunami wave corresponds to this general model of a 2D surface wave in terms of the energy being proportional to the square of the amplitude of the wave?
 
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  • #3
In response to points 7 and 8; the growth of wave amplitude si usually described as being a result of a focussing of the wave energy, so I would say yes, this is a sort of conservation of energy, and the volume of water displaced tries to remain constant by trading off wavelength for amplitude (wave height).
 
  • #4
7, 8 explain why a tsunami 'rears up' when it hits the coast.
I assume that if there was an island with no shallow water - just a steep volcanic peak in mid ocean (like La Palma) - then the tsunami would flow past with only a temporary small rise in sea level?
 
  • #5
Some quick thoughts that may require confirmation:

1. I believe this is true of a wave expanding with a spherical wave front. However, a tsunami is a surface wave and therefore has a cylindrical wavefront. This means that it loses energy proportional to the radius only, i.e. not the square of the radius, such that it does not attenuate as much due to geometric spreading as a spherical wave would.

2. Are those equations for the group or the phase velocity? The main package of energy travels at the group velocity so really this is the velocity that concerns us. The good thing is that the group velocity is slower than the phase velocity, so if you got it wrong and calculated the time the wave was going to hit you based on the phase velocity, you'd be the "right side" of wrong, if you catch my drift.

As the wave approaches shallower water, the group velocity of the front of the wave slows down but the back is still moving quicker so that the wave length is squished. As a direct consequence of this the amplitude of the wave increases simply by conservation of energy.
 
  • #6
billiards said:
However, a tsunami is a surface wave and therefore has a cylindrical wavefront. This means that it loses energy proportional to the radius only, i.e. not the square of the radius, such that it does not attenuate as much due to geometric spreading as a spherical wave would.
It could be even worse. If the Tsunami is caused by a landslip and that is long compared to the wavelength then it could be a sort of colimated beam

2. Are those equations for the group or the phase velocity? The main package of energy travels at the group velocity so really this is the velocity that concerns us. The good thing is that the group velocity is slower than the phase velocity, so if you got it wrong and calculated the time the wave was going to hit you based on the phase velocity, you'd be the "right side" of wrong, if you catch my drift.
Isn't a Tsunami a soliton?

As the wave approaches shallower water, the group velocity of the front of the wave slows down but the back is still moving quicker so that the wave length is squished. As a direct consequence of this the amplitude of the wave increases simply by conservation of energy.
Or just conservation of mass. It's really a single wave - a hump of water 1m high and 100km long, it's that extra few cubic km of water arriving that does the damage
 
  • #7
mgb_phys said:
7, 8 explain why a tsunami 'rears up' when it hits the coast.
I assume that if there was an island with no shallow water - just a steep volcanic peak in mid ocean (like La Palma) - then the tsunami would flow past with only a temporary small rise in sea level?
I can't say for certain, but I believe that is incorrect. The tsunami travels across the deep ocean as a long wavelength with low amplitude, then the leading edge encounters a cliff face. Rather than slowing down, like when approaching a normal beach, the front of the wave abruptly stops. I believe this will cause the remainder of the wave to mount up much more suddenly than it does when approaching land through shallow water.
 
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  • #8
Thanks for all the useful points raised. A few quick comments in response:
LURCH said:
In response to points 7 and 8; the growth of wave amplitude si usually described as being a result of a focussing of the wave energy, so I would say yes, this is a sort of conservation of energy, and the volume of water displaced tries to remain constant by trading off wavelength for amplitude (wave height).
I think that in the context of this Earth bound system, the conservation of energy would apply, but becomes very difficult to resolve due to factors such as ‘focussing` and seabed drag etc, especially in shallow water. This was why I was focusing on the deep water solution.
mgb_phys said:
I assume that if there was an island with no shallow water - just a steep volcanic peak in mid ocean (like La Palma) - then the tsunami would flow past with only a temporary small rise in sea level?
I tend to agree, but I think it depends on what scale you want to look at this problem. See post #7 for a slightly different take.
billiards said:
1. I believe this is true of a wave expanding with a spherical wave front. However, a tsunami is a surface wave and therefore has a cylindrical wavefront. This means that it loses energy proportional to the radius only, i.e. not the square of the radius, such that it does not attenuate as much due to geometric spreading as a spherical wave would.
Thanks, I made a typo, the equation should have been with respect to amplitude, i.e. the energy is the square of the amplitude, but the energy is distributed over the circumference of the wavefront at radius [r]:

[tex]A^2 = E/2 \pi r[/tex]
[tex]A \propto 1/\sqrt{r}[/tex] I corrected post2 to avoid confusion
billiards said:
2. Are those equations for the group or the phase velocity? The main package of energy travels at the group velocity so really this is the velocity that concerns us. The good thing is that the group velocity is slower than the phase velocity, so if you got it wrong and calculated the time the wave was going to hit you based on the phase velocity, you'd be the "right side" of wrong, if you catch my drift.
According to the Wikipedia reference, it’s the phase speed, which make sense because the Tsumani seems to correspond to a fundamental wave of long wavelength that would quickly leave behind any secondary modulated waves of shorter wavelength associated with a group velocity.
billiards said:
As the wave approaches shallower water, the group velocity of the front of the wave slows down but the back is still moving quicker so that the wave length is squished. As a direct consequence of this the amplitude of the wave increases simply by conservation of energy.
I think this is a good practical description, i.e. the front of wave slows first and as the back of the wave catches up, it causes the wave height to increase. The actual helight is determined by other physics, e.g. individual waves break when their wave height H is larger than 0.8 times the water depth h
mgb_phys said:
Isn't a Tsunami a soliton?
Thanks. I hadn’t heard this term before. http://en.wikipedia.org/wiki/Soliton

Again, thanks for the comments, but my main issue is still to try and get some physical understanding of the general assertion of wave mechanics that the energy of a mechanical wave is the square of its amplitude. However, when I looked at a tsunami wave, purely a practical example, the energy also seems dependent on the wavelength. I am making this statement because it seemed to me that the energy of this specific wave was reflected in the mass of the water displaced, which seems to be a function of not only the amplitude, but also the wavelength?
 
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  • #9
mysearch said:
1. The energy of a mechanical wave, i.e. one dependent on the physical interaction of the particles in the propagating medium is normally said to be proportional to the square of the amplitude of the wave.

2. Wikipedia has a page on ocean waves that gives a generalised solution of a wave’s propagation velocity: http://en.wikipedia.org/wiki/Ocean_surface_wave. However, this solution can be simplified for discussion by considering the following deep and shallow depth solutions:

[1] [tex]v = \sqrt { \frac {g\lambda}{2 \pi} } [/tex] deep water

[2] [tex]v = \sqrt { gd} [/tex] shallow water

3. Now descriptions of tsunami waves suggest that the amplitude of the wave is relatively small, e.g. 1 metre, but the wavelength is very long, e.g. 10-100km, in deep water. As such, equation [1] would suggest that these waves also move very fast.

4. However, if tsunami waves are classified as mechanical waves, they seem to conflict with the energy of the wave being proportional to the square of the amplitude.​

I have some thoughts of why this might be the case, but would like to get some general feedback on the specific issue associated with energy in bullet (4) above:

5. At some level, the energy of the wave seems to be related to the volume of water displaced by the crest and trough of the wave. In the case of tsunami waves, the energy-volume is still very large, even though the amplitude is small, because the wavelength is so long.

6. As the tsunami wave approaches shallow water, equation [2] would restrict the propagation velocity is a function of the depth of the water, not its wavelength.

7. Does the amplitude of the wave grow to compensate, i.e. is this some form of conservation of energy?

8. While I assume that some wave energy must be lost to friction in shallow water, is it correct to assume, in this specific case, that the wave energy is still characterised by the volume of water displaced, i.e. is this representative of potential energy?

9. Finally, does the propagation velocity of a mechanical wave reflect some sort of notion of the kinetic energy associated with the wave? I am asking this question because a SHM wave model cycles between potential and kinetic energy maxima​
Would appreciate any clarification of any of the issues raised. Thanks

Hi mysearch,

The energy is generally proportional to the square of the amplitude and the wavelength or [itex] E \propto \lambda a^2[/itex]. Since tsunamis have ridiculously long wavelengths it should seem reasonable to compare them. However, remember that ocean waves are highly non-linear by nature and that simplified models are only estimates for how they behave.

Nonetheless tsunamis are a wave phenomenon and will therefore follow certain physical laws defined for all waves. Tsunamis behave physically as shallow-water waves (i.e. non-dispersive) so their phase velocity = group velocity = [itex]\sqrt{gd}[/itex]. Of course this is just an approximation mind you. Plainly the velocity is tremendous for deepwater waves. This large velocity also indicates that they have an enormous amount of energy even though they have a small amplitude.

The rate of energy loss is typically proportional to the inverse of the wavelength. Thus tsunamis dissipate very little energy. In the absence of bottom friction, like in deep water, the wave maintains its large amount of energy. As the tsunami approaches the coast it will begin to slow and experience a run-up creating large surges.

To give a better understanding of how much energy is in the tsunami, it may be helpful to look at how much energy it takes to create it (and hence transferred to the wave). The energy in a tsunami wave can be defined mathematically as:

[tex] E = \frac{1}{2}\rho g \lambda La^2[/tex]

By inspection we see that the energy is indeed a function of the wavelength and the amplitude as suspected.

Hope this helps.

CS
 
  • #10
Hi Stewartcs,

Thank you very much, that was extremely helpful. I had been struggling to find any useful references in this area. However, could I just ask for some additional clarifications on a few of the points you made?

[tex] E = \frac{1}{2}\rho g \lambda La^2[/tex]

First, could you clarify the nature of the parameters [rho] and [L] as I am interested in whether they reflect the mass of water displaced in the originating event, which caused the wave. See my following diatribe for details. :redface:

By way of background, my interest is not directly with tsunami waves, I just happen to come across a description of them, which I couldn’t resolve in terms of general wave mechanics, i.e. the general statement that energy (E) is proportional to the square of the amplitude (A). I haven’t seen any mention of wavelength in standard text up until now. I was also looking into mechanical wave as opposed to EM wave, because of the different correlation to energy, i.e. Planck equation E=hf. Clearly, EM are also capable of propagate through a vacuum, whereas mechanical waves depend on ‘vibrations’ of neighbouring particles within the physical propagating media.
stewartcs said:
The energy is generally proportional to the square of the amplitude and the wavelength or [itex] E \propto \lambda a^2[/itex]. Since tsunamis have ridiculously long wavelengths it should seem reasonable to compare them. However, remember that ocean waves are highly non-linear by nature and that simplified models are only estimates for how they behave.
I think I understand the caveats concerning linearity, but is your statement concerning energy being related to amplitude and wavelength generally true for all mechanical waves? I ask because this seems to be of fundamental importance to anybody trying to gain some physical understanding of the nature of mechanical waves. For example, it seemed to me, although I admit this is just speculation, that a mechanical wave starts by acquiring energy from outside the wave system, which it then propagates through a medium. If I use the pebble-in-the-pond analogy, an initial central wave is created, e.g. meteor strike or seismic shift in the seabed, which then radiates outwards. However, given that there is no net propagation of water, only wave energy, does this energy correlate to the potential energy of the source?

What I mean by this is that the original event caused a large displacement of water, which had mass (m) and subject to gravity [g] due to its height (A) and width ([tex]\lambda[/tex]). Therefore, if this displacement disappears, i.e. the water returns to a flat surface, it would seem logical to assume that the wave carried away most of this potential energy. Of course, in the case of a radiating circular wave, the initial central energy of the water is dissipated across the increasing radius of the circumference wave.

Again, I am raising these points, because I am interested in trying to understand the interplay of potential and kinetic energy in mechanical waves. In a SHM model, the wave function persists because energy is converted from potential energy to kinetic energy and back again, assuming no loss to fiction etc. However, it seems that, in this case, the wave is propagating the original potential energy, although local particles within the propagating media are subject to kinetic movement, i.e. energy exchange.

I know I am pushing my luck, but I would also like to understand what determines the frequency/wavelength of a mechanical wave in the first place. For example, in the case of an EM wave in vacuum, energy defines the frequency, the vacuum `media` defines the propagation velocity [c] and therefore the wavelength is determined by virtue of [tex]c= f * \lambda[/tex]. Is there any analogous logic to mechanical waves?

Anyway, again many thanks for all your previous input.
 
  • #11
mysearch said:
Hi Stewartcs,

Thank you very much, that was extremely helpful. I had been struggling to find any useful references in this area. However, could I just ask for some additional clarifications on a few of the points you made?

[tex] E = \frac{1}{2}\rho g \lambda La^2[/tex]

First, could you clarify the nature of the parameters [rho] and [L] as I am interested in whether they reflect the mass of water displaced in the originating event, which caused the wave. See my following diatribe for details. :redface:

By way of background, my interest is not directly with tsunami waves, I just happen to come across a description of them, which I couldn’t resolve in terms of general wave mechanics, i.e. the general statement that energy (E) is proportional to the square of the amplitude (A). I haven’t seen any mention of wavelength in standard text up until now. I was also looking into mechanical wave as opposed to EM wave, because of the different correlation to energy, i.e. Planck equation E=hf. Clearly, EM are also capable of propagate through a vacuum, whereas mechanical waves depend on ‘vibrations’ of neighbouring particles within the physical propagating media.

I think I understand the caveats concerning linearity, but is your statement concerning energy being related to amplitude and wavelength generally true for all mechanical waves? I ask because this seems to be of fundamental importance to anybody trying to gain some physical understanding of the nature of mechanical waves. For example, it seemed to me, although I admit this is just speculation, that a mechanical wave starts by acquiring energy from outside the wave system, which it then propagates through a medium. If I use the pebble-in-the-pond analogy, an initial central wave is created, e.g. meteor strike or seismic shift in the seabed, which then radiates outwards. However, given that there is no net propagation of water, only wave energy, does this energy correlate to the potential energy of the source?

What I mean by this is that the original event caused a large displacement of water, which had mass (m) and subject to gravity [g] due to its height (A) and width ([tex]\lambda[/tex]). Therefore, if this displacement disappears, i.e. the water returns to a flat surface, it would seem logical to assume that the wave carried away most of this potential energy. Of course, in the case of a radiating circular wave, the initial central energy of the water is dissipated across the increasing radius of the circumference wave.

Again, I am raising these points, because I am interested in trying to understand the interplay of potential and kinetic energy in mechanical waves. In a SHM model, the wave function persists because energy is converted from potential energy to kinetic energy and back again, assuming no loss to fiction etc. However, it seems that, in this case, the wave is propagating the original potential energy, although local particles within the propagating media are subject to kinetic movement, i.e. energy exchange.

I know I am pushing my luck, but I would also like to understand what determines the frequency/wavelength of a mechanical wave in the first place. For example, in the case of an EM wave in vacuum, energy defines the frequency, the vacuum `media` defines the propagation velocity [c] and therefore the wavelength is determined by virtue of [tex]c= f * \lambda[/tex]. Is there any analogous logic to mechanical waves?

Anyway, again many thanks for all your previous input.

The parameters [itex] \rho [/itex] and L are representative of the mass of the wave. [itex] \rho[/itex] is the water density and L describes part of the volume of the water ([itex]\lambda[/itex] and the amplitude describe the rest). The initial seismic event causes a transfer of energy to the water by displacing it upward. This energy, for the most part, is carried along all the way to the coastline with little dissipation as previously noted in the form of a wave.

Note that the direction of the tsunami wave is mainly orthogonal to the direction of the seismic fault line.

Generally speaking the energy of a mechanical wave is typically not dependent on the wavelength, rather only proportional to the square of amplitude. However, I presumed you were only talking about tsunamis which behave slightly differently than a normal mechanical wave (although they are very similar as described above). The total energy initially transferred to the tsunami wave was given above as E, which is dependent on the wavelength.

Hope this helps.

CS
 
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  • #12
Thanks for the clarification of the equation. The dependency on the mass of the wave makes sense, if the source of the energy being dissipated by the wave is proportional to the potential energy of the event that caused the wave.
stewartcs said:
Note that the direction of the tsunami wave is mainly orthogonal to the direction of the seismic fault line.
Does this preclude a tsunami being modeled on the pebble-in-the-pond analogy, i.e. a meteor in the middle of the Pacific causes a radially expanding tsunami?
stewartcs said:
Generally speaking the energy of a mechanical wave is typically not dependent on the wavelength, rather only proportional to the square of amplitude.
Actually, this is still my central issue. If mechanical waves have a potential energy source, then I don’t understand how amplitude alone is really representative. I accept that, as in the case of tsunami waves, the energy of a mechanical wave may well always be proportional to the square of the amplitude, but this seems to be only part of the equation.

[tex]v = \sqrt{\frac{T}{\mu}}[/tex]

For example, I found the propagation formula above for a wave on a string, where [T] is tension and [mu] is linear mass, although I have not had much luck in finding any direct energy related equations for a string wave. However, just guessing, I would have thought that the energy of this type of wave would also be a function of the amplitude and wavelength linked to the linear mass of the string?

One final point of interest, while there are many sources that specify various equations for the propagation velocity [v] and the fundamental equation [tex]v= f \lambda[/tex], there seems to be little discussion of how to determine either the frequency or wavelength of a mechanical wave from this product relationship. I am assuming the type of media affects the outcome?
 
  • #13
mysearch said:
Does this preclude a tsunami being modeled on the pebble-in-the-pond analogy, i.e. a meteor in the middle of the Pacific causes a radially expanding tsunami?

No, not for a meteor strike.

mysearch said:
Actually, this is still my central issue. If mechanical waves have a potential energy source, then I don’t understand how amplitude alone is really representative. I accept that, as in the case of tsunami waves, the energy of a mechanical wave may well always be proportional to the square of the amplitude, but this seems to be only part of the equation.

[tex]v = \sqrt{\frac{T}{\mu}}[/tex]

For example, I found the propagation formula above for a wave on a string, where [T] is tension and [mu] is linear mass, although I have not had much luck in finding any direct energy related equations for a string wave. However, just guessing, I would have thought that the energy of this type of wave would also be a function of the amplitude and wavelength linked to the linear mass of the string?

Perhaps this will help:

"The amount of energy carried by a wave is related to the amplitude of the wave. A high energy wave is characterized by a high amplitude; a low energy wave is characterized by a low amplitude. The amplitude of a wave refers to the maximum amount of displacement of a particle on the medium from its rest position. The logic underlying the energy-amplitude relationship is as follows: If a slinky is stretched out in a horizontal direction and a transverse pulse is introduced into the slinky, the first coil is given an initial amount of displacement. The displacement is due to the force applied by the person upon the coil to displace it a given amount from rest. The more energy that the person puts into the pulse, the more work which he/she will do upon the first coil. The more work which is done upon the first coil, the more displacement which is given to it. The more displacement which is given to the first coil, the more amplitude which it will have. So in the end, the amplitude of a transverse pulse is related to the energy which that pulse transports through the medium. Putting a lot of energy into a transverse pulse will not effect the wavelength, the frequency or the speed of the pulse. The energy imparted to a pulse will only effect the amplitude of that pulse"

Source: http://www.glenbrook.k12.il.us/gbssci/Phys/Class/waves/u10l2c.html [Broken]

mysearch said:
One final point of interest, while there are many sources that specify various equations for the propagation velocity [v] and the fundamental equation [tex]v= f \lambda[/tex], there seems to be little discussion of how to determine either the frequency or wavelength of a mechanical wave from this product relationship. I am assuming the type of media affects the outcome?

IIRC, the source of the energy that creates the wave and the medium (if any) in which it propagates determine these.

Hope this helps.

CS
 
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  • #14
CS,
Really appreciate the help. I am trying to read deeper into the issues in the background, but it is useful to use this thread to resolve some the issues that initially puzzled me.
stewartcs said:
”…Putting a lot of energy into a transverse pulse will not effect the wavelength, the frequency or the speed of the pulse. The energy imparted to a pulse will only effect the amplitude of that pulse….”
This seems a categorical statement, which I need to consider. However, one of the interesting things about wave mechanics is applying the theory to real-world situations.

For example, a weight on a spring acting as lossless SHM pendulum can be described in terms of a sine wave. The initial vertical displacement defines the potential energy being put into the system: [tex]1/2kA^2[/tex], which reduces to zero as the mass springs back through the equilibrium point, having been totally converted to kinetic energy at this specific point. In this example, the square of the amplitude of the wave seems to unambiguously reflect the potential energy at any position without reference to wavelength. This example can also calculate the angular frequency ([tex]w=\sqrt{k/m}[/tex]) as function of 2 physical attributes of the media, i.e. elasticity and mass, which does indeed suggests that the media defines frequency, at least, in this case. However, there doesn’t appear to be any real propagation velocity, as the wave seems to be essentially a function of time only.

In the case of a surface wave, things don’t seem so straightforward. Presumably, these waves are more like a pulse than sine wave, although I am assuming a Fourier series would allow the pulse to be modeled as fundamental sine wave plus its harmonic components? It also seems difficult to associate the potential energy of this type of wave to a specific point, as per the example above, because this energy seems to associated with the pulse/wave as a whole, i.e. height (A) and width ([tex]\lambda[/tex]) etc. The issues of any conversion between potential and kinetic forms also seems less obvious, but presumably is required in any real world propagation process? Finally, while we have touched on several equations that specify a propagation velocity for this type of wave, I haven’t come across any equation that actually allow the frequency/wavelength to be calculated as a function of the media ,as per the SHM, possibly it is too complex to generalise?

Anyway, many thanks for all the help.
 
  • #15
Hi,
I was wondering if anybody was in a position to answer any of the additional questions about tsunami waves below. In post #9, the following equation was cited for the energy associated with a tsunami wave:

[tex] E = \frac{1}{2}\rho g (\lambda L)a^2[/tex]

http://www.scribd.com/doc/4633126/Fisika-The-Physics-of-Tsunami [Broken]
I tracked down a few papers that reference this equation and it appears to be based on a model of a wave with a volume of water referred to a `waterberg`. However, it seems that the essence of this equation can be reduced to the classical equation for potential energy:

[tex]E_p = mgh = \rho (x*y*z) * g * y/2 = \frac{1}{2} \rho g (x z) y^2[/tex]

Where mass [m] is the volume [x,y,z] times density and [y/2] is the average height. Note: these equations still reflect that the energy (E) of the wave is proportional to the square of its amplitude, but the huge energy of a tsunami is really a reflection of the net volume of the wave based on its very long wavelength. However, this analysis appears to be predicated on the fact that most tsunami waves are caused by seismic events, where the wavefront generated is essentially aligned and orthogonal to the direction of a seismic fault line. These papers also suggest a number of assumptions that I would like to raise for clarification:

1. While tsunami waves exist in deep water, because the wavelength can be much greater than the sea depth, they are often modeled using the shallow water equations cited in post #1.

2. While deep water is said to be dispersive, shallow water appears to be modeled as non-dispersive. Given the assumption in bullet (1) does it follow that tsunami waves should be modeled as non-dispersive?

3. In a non-dispersive medium, the equation [tex][v=f \lambda][/tex] holds for all frequencies, as long as the characteristics of medium do not change, i.e. the phase velocity of all waves of different frequency is the same?

4. Can a tsunami be modeled as a Fourier series of different frequency components?

5. Would these frequencies travel at the same phase velocity based on bullet (3)?​

It is said that due to their long wavelength, tsunami waves dissipate very little energy. However, I have attached a diagram that is more representative of a circular expanding wave, which by definition would dissipate its energy over an ever-increasing circumference – see post #2/#8.

6. Is this a valid model for a tsunami wave?

7. While the initial energy would still be proportional to the volume of water displaced; would it make sense to model this example on the volume of a cone?

8. While the propagation of a wave involves a local conversion of potential energy to kinetic energy, i.e. initial wave height into a rate of change of amplitude, is it true to say that only potential energy is being transported by the wave?

9. With reference to the attached diagram; what would determine the very long wavelength generally associated with tsunami waves?​
Appreciate that all these questions may be excessive, but would appreciate any insights or clarification of any of the issues. Thanks
 

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  • #16
mysearch said:
1. While tsunami waves exist in deep water, because the wavelength can be much greater than the sea depth, they are often modeled using the shallow water equations cited in post #1.

2. While deep water is said to be dispersive, shallow water appears to be modeled as non-dispersive. Given the assumption in bullet (1) does it follow that tsunami waves should be modeled as non-dispersive?

Yes, they should be modeled as non-dispersive.

Deep-water approximation refers to the depth of the water divided by the wavelength. Tsunamis have wavelengths of hundreds of kilometers, so they are shallow water waves.

However, most shallow water and deep water waves are somewhat dispersive. Tsunamis are just slightly dispersive so they are most accurately modeled as non-dispersive waves even though they may exist in deepwater. Only solitons are non-dispersive.

If you are looking for a Tsunami model, check out the NOAA Tsunami site. They give some details (IIRC) about how they do it.

Hope this helps.

CS
 
  • #17
stewartcs said:
Yes, they should be modeled as non-dispersive…
Tsunamis are just slightly dispersive so they are most accurately modeled as non-dispersive waves even though they may exist in deepwater….
If you are looking for a Tsunami model, check out the NOAA Tsunami site.
Thanks. Approximating to non-dispersive will allow a simplification of the frequency spread by propagation velocity. Based on the shallow water model, can the propagation equation still be equated to frequency * wavelength, e.g.

[tex]v = \sqrt{gd} = f * \lambda[/tex]?

I will assume that the circular model is possible for tsunamis and therefore the energy in successive radiating circular waves must fall as stated. However, is the ultra long wavelength primarily established, in most practical cases, by the seabed lifting/falling over a very large area?

I will take this displacement of a large volume of water as the initial potential energy input into the wave system, which is radiated away by successive circular waves. If I assume no net radial movement of water, the kinetic energy would seem to only exist in the localised rise and fall of the wave. However, it would seem that the energy of any section of the wave, in motion, at any radius must be the sum of this kinetic energy plus the potential energy associated with the amplitude of the wave and its wavelength. As such, the total energy being transported by the wave exists in both kinetic and potential forms.

Given that the kinetic energy exists as a function of the potential energy, i.e. wave amplitude, it will also be proportional to the square of the amplitude aggegated over the wavelength.
 
  • #18
mysearch said:
Thanks. Approximating to non-dispersive will allow a simplification of the frequency spread by propagation velocity. Based on the shallow water model, can the propagation equation still be equated to frequency * wavelength, e.g.

[tex]v = \sqrt{gd} = f * \lambda[/tex]?

Yes. In fact the approximate definitions for the phase speed are found from that relation.

Starting with the relations:

[tex]c = f \lambda[/tex]

or

[tex]c = \frac{\omega}{k}[/tex]

where,
c is the phase speed
k is the wave number

and

[tex]\omega^2 = gk^2d[/tex], which is the shallow water dispersion relation

We get:

[tex]c = \sqrt{gd} [/tex]

CS
 
  • #19
Thanks again for the previous clarification. I have one final set of energy related issues that I am trying to resolve, which stems from the general statement that the energy of a mechanical wave is proportional to the square of the amplitude. While I am not disputing this statement, it seems to provide only a small part of the picture of the energy distribution within a wave system like a tsunami.

1. In the case of a tsunami, the wave amplitude (1m) masks the real implications of the total energy associated with the very long wavelength (10-100km). However, the amplitude and wavelength in isolation do not seem to account for the kinetic energy associated with the water mass in motion [tex][1/2mv^2][/tex] over a complete wavelength?

2. As previously outlined, the initial energy can be approximated by estimating the potential energy associated with the central displacement of water, e.g. waterberg or cone. However, I would have thought that this total input energy is radiated outwards in a succession of waves, not just one, because the collapse of the central displacement of water gains kinetic energy, which causes the water to undulated/oscillate for some time, i.e. secondary waves are generated?

3. If you consider any cross-section of the expanding circular wave over a complete cycle, its dynamic up-down motion contains kinetic energy as well as potential energy. For example, if you modeled the water surface as analogous to a series of SHM spring-pendulums:

[tex]Et = Ep + Ek[/tex] aggregated over 1 wavelength
[tex]Ep = 1/2ky^2[/tex] aggregated over 1 wavelength
[tex]Ek = Et - Ep[/tex] aggregated over 1 wavelength

If so, a wave would be propagating both potential and kinetic energy, when viewed over a complete cycle. This total energy does not oscillate as per its potential and kinetic components and, as such, is not proportional to the square of the wave amplitude, although in all practical examples it would be subject to decay?​
 
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  • #20
I'm in no way knowledgeable about this subject so my question may sound simple to you folks.

In trying to follow along here, I'd like to know how high a tsunami can get, before it can't get any higher?

I'm getting that tsunamis are usually fairly low, but grow when they hit shallow water, like at landfall or just before. Is the height of the wave at landfall determined by how long the wave was in the first place? In other words, how much of the wave length is transformed into height?

In another conversation elsewhere, it has been proposed that an impact event outside Gibraltar, (that COULD have destroyed Atlantis IF she had existed there) would cause waves about 300 meters high at Athens. I'm naysaying that based on my minimal education, that the straight of Gibraltar would break the momentum at first, and then the islands within the Med. would further thwart the wave so that by the time it reached Greece, it wouldn't be any larger than a wave conjured up by a good storm.

I was looking for information on the dissipation of a tsunami when I saw this thread.
Thanks for any help you can give me.
 
  • #21
I have always understood the Tsunami to be an example of a soliton wave.

http://en.wikipedia.org/wiki/Soliton

A good description is given in the Cambridge Text in Applied Mathematics


Solitons an Introduction
by
PG Drazin and RS Johnson

Of course it rather depends what you mean by the Tsunami. The single huge wave riding on the surface is a soliton.
But the underlying phenomenon is a standing wave, usually generated by ocean floor movements. As such it is not just a surface effect, the whole of the water in the basin participates. Wavelengths can be enormous - several hundred kilometres.
 
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  • #22
Thanks for your reply. I think I understand what you're saying about the wave itself. I am talking about a wave(s) caused by an impact event. Specifically, an impact event in the Atlantic, outside the Straits of Gibraltar. Would the Strait itself allow only a part of the wave to proceed inside the Med, and once it WAS inside the Med., how would it dissipate? Would there be a lot of damage to the islands closest to the Strait, or would the Strait break it up, and how much energy would the wave have left, by the time it hit Greece?
 

1. What causes a tsunami wave?

Tsunami waves are typically caused by large disturbances in the ocean such as earthquakes, volcanic eruptions, or even meteorite impacts. These events create massive displacements of water, resulting in the formation of powerful waves.

2. How fast do tsunami waves travel?

Tsunami waves can travel at speeds of up to 500 miles per hour, depending on the depth of the ocean and the force of the initial disturbance. However, as they approach shallow waters, their speed decreases, causing the waves to increase in height.

3. What is the difference between a tsunami wave and a regular ocean wave?

Tsunami waves are distinct from regular ocean waves in their wavelength, speed, and energy. Tsunami waves have much longer wavelengths, often stretching hundreds of miles, and travel at much higher speeds than regular waves. They also carry a significantly larger amount of energy, making them much more destructive.

4. How do scientists measure and track tsunami waves?

Scientists use a variety of instruments, such as seismometers, buoys, and satellite imagery, to measure and track tsunami waves. Seismometers detect earthquakes and other seismic activity that can trigger a tsunami, while buoys and satellites can detect the height and speed of the waves as they travel through the ocean.

5. Can tsunami waves be predicted?

While scientists can predict the likelihood of a tsunami occurring based on seismic activity, it is difficult to predict the exact size and timing of a tsunami wave. However, advancements in technology and early warning systems have greatly improved our ability to warn coastal communities and mitigate the impact of these destructive waves.

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