We can't have elastic scattering even theoretically

In summary: the total energy is conserved, if the photon loses a tiny fraction of its energy and the crystal gains a tiny bit (in the initial frame of the crystal), it is still called elastic scattering.
  • #1
hokhani
483
8
Consider a photon which is scattered by a crystal elastically. In an elastic scattering we have [itex]
|k_i|=|k_f| and k_f - k_i = G
[/itex] where [itex]
G
[/itex] is a reciprocal vector. But according to momentum conservation, the crystal must obtain a momentum [itex]
\hbar G
[/itex] and hence the kinetic energy, so according to energy conservation we no longer have [itex]
|k_i|=|k_f|
[/itex] because some of the energy of incident photon is transferred to the crystal and this is a contradiction!
 
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  • #2
I am unsure of what you are trying to say. A change in momentum (being a vector) does not necessarily imply a change in energy (see for example a charged electron whose path is curved when entering a constant magnetic field). Additionally, in quantum mechanics momentum is related to the wavelength or the particle (or k) through

[tex]p=\hbar k [/tex] which relates to the SPATIAL behavior of the wave/particle where energy is related to the frequency (or ω) through

[tex]E =\hbar \omega [/tex]

which is to say it relates to the TEMPORAL behavior of the wave. Furthermore, you have to think about what G means spatially. It is just a bravais lattice vector and essentially is just encoding WHICH plane has interfered constructively with the incident surface ray in order to get a bragg peak.
 
  • #3
Actually, I've thought about it a bit more and I believe it's a little more subtle. Because you have perfect reflectance there is no net energy being transported to the sample, however, I believe you may have an entire net motion of the lattice (without any local distortion) along the direction of G. However, this motion carries no energy in the sense that it does not represent any heat.
 
  • #4
maverick_starstrider said:
Actually, I've thought about it a bit more and I believe it's a little more subtle. Because you have perfect reflectance there is no net energy being transported to the sample, however, I believe you may have an entire net motion of the lattice (without any local distortion) along the direction of G. However, this motion carries no energy in the sense that it does not represent any heat.
Somehow, I think it is an impossible thing.
 
  • #5
Well of course it's impossible. No lattice is infinite, no lattice is a perfect reflector, no angle is perfect.
 
  • #6
I'm not good at solid state physics but I think I can say this much.
At first,I remember that reciprocal space is not momentum space but pseudo-momentum space because the symmetries of a crystal are not continuous.This may cause some changes in the reasoning!
Second,the motion of the crystal as a whole,can be eliminated by a change of coordinate system so it shouldn't have physical meaning and so it shouldn't be taken into account in calculating the change of energy.
Third [itex] |k_i|=|k_f| [/itex] is derived from assuming that there is no change of energy(The meaning of [itex] k_f-k_i=G [/itex] being only a change of direction caused by scattering)and so the argument you're presenting becomes cyclic!
 
  • #7
Shyan said:
At first,I remember that reciprocal space is not momentum space but pseudo-momentum space because the symmetries of a crystal are not continuous.This may cause some changes in the reasoning!

We examine the crystal momentum rather than real momentum.

Shyan said:
Second,the motion of the crystal as a whole,can be eliminated by a change of coordinate system so it shouldn't have physical meaning and so it shouldn't be taken into account in calculating the change of energy.

Ok, But have an external particle such as neutron which is incident on the crystal so the change of neutron momentum must be equal to change of real momentum of crystal as a whole.

Shyan said:
Third [itex] |k_i|=|k_f| [/itex] is derived from assuming that there is no change of energy(The meaning of [itex] k_f-k_i=G [/itex] being only a change of direction caused by scattering)and so the argument you're presenting becomes cyclic!

We can not neglect the energy of crystal as a whole.
 
  • #8
hokhani said:
Consider a photon which is scattered by a crystal elastically. In an elastic scattering we have [itex]
|k_i|=|k_f| and k_f - k_i = G
[/itex] where [itex]
G
[/itex] is a reciprocal vector. But according to momentum conservation, the crystal must obtain a momentum [itex]
\hbar G
[/itex] and hence the kinetic energy, so according to energy conservation we no longer have [itex]
|k_i|=|k_f|
[/itex] because some of the energy of incident photon is transferred to the crystal and this is a contradiction!
There is always a reference frame (actually, there are many those systems) where the photon energy is constant. The crystal will move in that system.

Not that it would be relevant... the total energy is conserved, if the photon loses a tiny fraction of its energy and the crystal gains a tiny bit (in the initial frame of the crystal), it is still called elastic scattering.

hokhani said:
We can not neglect the energy of crystal as a whole.
Sure you can. In the same way you can neglect the gravitational influence of Pluto on the crystal. It is there, but you don't care.
 
  • #9
A similar thing occurs in the Moessbauer effect. Here a photon is absorbed by a nucleus. The energy of the photon excites the nucleus to an excited level. The momentum of the photon is transferred onto the entire crystal lattice.
Because even a tiny crystal has a huge mass compared to the photon, the velocity gain of the crystal is extremely small, v = p/m. For the same reason the kinetic energy gained in this inelastic collision is very small, E=p^2/2m (assuming we are in the rest frame of the crystal before the absorption).

In Moessbauer spectroscopy this has been verified experimentally. The relative line with of Moessbauer resonances is something like 10^-15 (!), and the energy loss to the crystal is well below that.

The same argument holds for neutron or x-ray diffraction. There is a real momentum transfer from the neutron or photon onto the crystal, but onto the crystal as a whole. Because of the mass of the crystal the associated energy transfer is so small that it can be safely neglected.

In might be interesting to see if the energy shift is measurable for nanoparticles. I am afraid, however, that one would need free nanoparticles - if they are embedded or attached to something heavy we would be in the same case as above. If someone wants to do a back-of-the-envelope calculation, I'd be interested in the result :)
 
  • #10
All these reasoning don't convince the main problem. Though the crystal mass is very large that doesn't move significantly, but the energy transferred to the crystal may be at least comparable to the energy of incident particle so the energy of the scattered particle must be less than that of when impinging.
 
  • #11
momentum transfer = p = hbar (k_out - k_in) for a photon.
associated energy transfer = p^2/2m

for a very large mass, the energy for a given momentum is simply very very small. In theory one often assumes infinite crystals, i.e. infinite mass. Then the energy transfer goes to zero.
 
  • #12
hokhani said:
All these reasoning don't convince the main problem. Though the crystal mass is very large that doesn't move significantly, but the energy transferred to the crystal may be at least comparable to the energy of incident particle so the energy of the scattered particle must be less than that of when impinging.
If you call 0.000000000000000000000000000001 of the energy comparable... sure, it is comparable in the literal way (I just did that by giving a typical fraction), but it is completely negligible.
 
  • #13
This is a very interesting question/problem on which I have been working for a long time. I believe, elastic scattering is impossible even theoritically. My analysis is based on the theory of elastic collisions in classical mechanics where the problem has its origin. The problem finds its way into every branch of modern physics - for example QM, Relativity, particle physics etc.

It is better and even simple to tackle the problem at its origin - in classical mechanics.

Origin of the problem lies in the fact that in a binary elastic collision in the center of mass reference frame the velocity vectors of the particles change their directions through equal angles other than 1800 while keeping their respective magnitudes unchanged. That is, the relative velocity vector rotates through an angle not equal to 1800! The relative velocity vector does not change its sign.This process came to be called elastic scattering. This essentially is Newton's result, in contrast to Huygen's result that demands that in a binary elastic collision process the relative velocity vecor changes sign as a result of elastic collision.

The result of rotation (but not reversal) of relative velocity vector is a consequence of the model based on finite sized particles (in contrast to point masses) giving rise to the possibility of oblique collisions and there by to scatter. With point masses oblique collisions and consequential scatter are impossible even in principle! Thus, the model of finite sized masses in contrast to point sized masses leads to this paradox of elastic scattering.

We may incidentally note that:

Maxwell derived a result that showed transfer of kinetic energy (KE) from the mass of higher (KE) to the mass with lower KE during an elastic collision so that the difference in KEs after collision is necessarily less than the difference in KEs before collision. This is the origin of irreversibility being brought into thermodynamics through the model of ideal gases involving elastic collisions.
 
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  • #14
Radhakrishnam said:
Origin of the problem lies in the fact that in a binary elastic collision in the center of mass reference frame the velocity vectors of the particles change their directions through equal angles other than 1800 while keeping their respective magnitudes unchanged. That is, the relative velocity vector rotates through an angle not equal to 1800! The relative velocity vector does not change its sign.This process came to be called elastic scattering. This essentially is Newton's result, in contrast to Huygen's result that demands that in a binary elastic collision process the relative velocity vecor changes sign as a result of elastic collision.
I think you are mixing two different "relative velocities" here, and I don't see where you see something special about 180°.

The velocity of objects relative to the center of mass changes by an angle other than 0° - it can be 180°, it does not have to be.
The velocity of object 1 relative to object 2 changes by an angle other than 0° - it can be 180°, it does not have to be.

With point masses oblique collisions and consequential scatter are impossible even in principle!
Not if you include their spin ;). But arbitrary angles are possible with point masses (again apart from 0°, as this is a non-interaction and not called "collision").

There is no "paradox of elastic scattering".

Maxwell derived a result that showed transfer of kinetic energy (KE) from the mass of higher (KE) to the mass with lower KE during an elastic collision so that the difference in KEs after collision is necessarily less than the difference in KEs before collision.
That is certainly wrong.
 
  • #15
I think you are mixing two different "relative velocities" here, and I don't see where you see something special about 180°.

I am talking about the relative velocity of particle 1 with respect to velocity of particle 2. According to Huygens' analysis, this relative velocity changes sign as a result of elestic collision. In other words, reversal of relative velocity is a necessary consequence of a binary elastic collision. This makes elastic scattering impossible.

However, according to Newton's analysis, restitution of relative speed is a necessary consequence of a binary elastic collision, but not reversal of relative velocity. This makes it possible for rotation of relative velocity vector through any non zero angle, including 180o. This makes elastic scattering possible.

Not if you include their spin ;). But arbitrary angles are possible with point masses (again apart from 0°, as this is a non-interaction and not called "collision").

In the case of point masses, the value of the 'b' parameter is zero and there is no possiility of oblique collision and no possibility of scattering. If you are not considering collisions we will not be discussing about one and the same issue.

That is certainly wrong.

The way Maxwell accounts for equivalization of temeratures of two gas samples at different temperatures goes somewhat like this: Suppose we mix in a rigid adiabatic container two ideal gas samples at different temperatures and leave them. They come to a common temperature - the equilibrium temperature. The mechanism of the process of equilibrization of temperatures is explained by Maxwell through the agency of binary elastic collisions between molecules wherein molecules with higher KE transfer energy to molecules with lower KE thereby bringing their KEs (temperatures) closer together. After a large number of such collisions the temerature difference of the two samples disappears and they assume the equilibrium temperature.

This mechanism is untenable.

Do you agre with that mechanism or think it is wrong mechanism?
 
  • #16
Please use
-tags for quotes.

Radhakrishnam said:
I am talking about the relative velocity of particle 1 with respect to velocity of particle 2. According to Huygens' analysis, this relative velocity changes sign as a result of elestic collision. In other words, reversal of relative velocity is a necessary consequence of a binary elastic collision.
Source? For 1-dimensional collisions, this is true, for other collisions it is not.
This makes elastic scattering impossible.
No. Why should it?


What do you mean with "restitution of relative speed"? Google finds exactly zero hits for this expression (in quotation marks).

In the case of point masses, the value of the 'b' parameter is zero
No. Point masses can have fields around them, like two charged point-particles.
and there is no possiility of oblique collision and no possibility of scattering.
Even if you want to consider point-like collisions (which have a probability of 0 to happen in real setups), this is still possible.

If you are not considering collisions we will not be discussing about one and the same issue.
Every collision is an interaction between fields and particles. If you smash two objects together, the electromagnetic interaction prevents them from going through each other.

The way Maxwell accounts for equivalization of temeratures of two gas samples at different temperatures goes somewhat like this: Suppose we mix in a rigid adiabatic container two ideal gas samples at different temperatures and leave them. They come to a common temperature - the equilibrium temperature. The mechanism of the process of equilibrization of temperatures is explained by Maxwell through the agency of binary elastic collisions between molecules wherein molecules with higher KE transfer energy to molecules with lower KE thereby bringing their KEs (temperatures) closer together. After a large number of such collisions the temerature difference of the two samples disappears and they assume the equilibrium temperature.
This is a statement about the average. Not for each collision.

Do you agre with that mechanism or think it is wrong mechanism?
Which mechanism? If you mean the thermal equilibrium: it is not relevant for this topic.
 
  • #17
Source?

H. Erlichson, Am. J. Phys. 65 (2), 149-154 (1997)

No. Why should it?

If we accept reversal of relative velocity as a necessary consequence of a binary elastic collision, then it follows that elastic scattering is impossible.

What do you mean with "restitution of relative speed"? Google finds exactly zero hits for this expression (in quotation marks).

I mean restoration of relative speed or coefficient of restitution is one.

No. Point masses can have fields around them, like two charged point-particles.

Let us not bring fields into picture, they are not necessary to discuss elastic collision phenomena in classical mechanics.

Even if you want to consider point-like collisions (which have a probability of 0 to happen in real setups), this is still possible.

With point masses, it is impossible to have oblique collisions and therefore scattering. We are interested what is possible in principle. Thus the probability arguments do not enter our discussion.

Every collision is an interaction between fields and particles. If you smash two objects together, the electromagnetic interaction prevents them from going through each other.

As I stated above, we shall restrict our discussion to classical mechanics for the sake of simplicity and shall not bring in fields.

This is a statement about the average. Not for each collision.

You may please this: J. C. Maxwell, The dynamical Theory of Gases in

Selected readings in physics: Kinetic theory vol. 1, Stephen

Brush, Pergamon Press, New York (1966), pp. 151-152.
 

What is elastic scattering?

Elastic scattering refers to a type of collision between particles where the total kinetic energy of the system is conserved. This means that the particles involved do not lose or gain energy during the interaction.

Why can't we have elastic scattering theoretically?

In classical mechanics, elastic scattering is possible because the particles are treated as point particles with no internal structure. However, in quantum mechanics, particles are described as waves and can interact with each other in ways that lead to energy exchange. This makes it impossible to have perfect elastic scattering theoretically.

Are there any real-world examples of elastic scattering?

Yes, there are several examples of elastic scattering in everyday life. For instance, when a light beam passes through a glass window, it undergoes elastic scattering. Additionally, elastic scattering is also observed in the collisions between subatomic particles in particle accelerators.

What is the significance of elastic scattering in physics?

Elastic scattering plays a crucial role in understanding the behavior of particles and their interactions. It helps us study the properties of particles and their internal structure. Additionally, elastic scattering is also used in various experimental techniques to study the properties of materials and substances.

Can elastic scattering ever occur perfectly?

No, perfect elastic scattering is not possible even theoretically. This is because particles are constantly interacting with each other through various forces, and these interactions can lead to energy exchange. However, in some cases, elastic scattering can be approximated with a high degree of accuracy, making it a useful concept in physics.

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