FAQ - Do Photons Move Slower in a Solid Medium?

In summary, photons move slower in a solid medium due to the collective behavior of atoms and molecules forming the medium, which causes a slight delay in the re-emission of the photon after being absorbed. This delay is not due to an "atomic transition" as commonly explained, but rather the ability of the medium to be electrically polarized. This applies to both solids and liquids, and the slowing of light does not necessarily require absorption. The size of a photon is not relevant in this explanation, as it is described by a wave function rather than a point particle.
  • #1
Usaf Moji
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FAQ - "Do Photons Move Slower in a Solid Medium?"

I have a question regarding this post in the FAQ's:

A common explanation that has been provided is that a photon moving through the material still moves at the speed of c, but when it encounters the atom of the material, it is absorbed by the atom via an atomic transition. After a very slight delay, a photon is then re-emitted. This explanation is incorrect and inconsistent with empirical observations. If this is what actually occurs, then the absorption spectrum will be discrete because atoms have only discrete energy states. Yet, in glass for example, we see almost the whole visible spectrum being transmitted with no discrete disruption in the measured speed. In fact, the index of refraction (which reflects the speed of light through that medium) varies continuously, rather than abruptly, with the frequency of light.

Secondly, if that assertion is true, then the index of refraction would ONLY depend on the type of atom in the material, and nothing else, since the atom is responsible for the absorption of the photon. Again, if this is true, then we see a problem when we apply this to carbon, let's say. The index of refraction of graphite and diamond are different from each other. Yet, both are made up of carbon atoms. In fact, if we look at graphite alone, the index of refraction is different along different crystal directions. Obviously, materials with identical atoms can have different index of refraction. So it points to the evidence that it may have nothing to do with an "atomic transition".

When atoms and molecules form a solid, they start to lose most of their individual identity and form a "collective behavior" with other atoms. It is as the result of this collective behavior that one obtains a metal, insulator, semiconductor, etc. Almost all of the properties of solids that we are familiar with are the results of the collective properties of the solid as a whole, not the properties of the individual atoms. The same applies to how a photon moves through a solid.

My question is, to what extent is the above applicable to photons moving through a liquid medium? Do the atoms and molecules that form a liquid also lose their individual identity and form a collective behaviour that governs the transmission of photons?
 
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  • #2


You have the mistaken impression that the answer to why "Photons Move Slower in [any] Medium" is primarily the result of "the collective properties of the [medium] as a whole, not the properties of the individual atoms". Quite simply, it is false (not just naive) that "disturbance of the lattice [..] is the origin of the apparent slowdown of the light speed in the material".

Light is slowed even in a dilute gas. Slowing of light requires only one property: that the medium has some small ability to be electrically polarised. All atoms have this property individually (a small perturbation in electric field causes a small perturbation in electron distribution around the nucleus, even without actually "exciting" the electron). [See https://www.physicsforums.com/showthread.php?t=173745".]
 
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  • #3


The speed of light is about half in diamond. Think back to the glass block experiments where the light was refracted because it moved slower in the glass than in air.
 
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So if diffraction is not an atom being absorbed and reemitted, what is reflection? Is the reflected photon the _same_ photon that hit the mirror? I assume the answer is no - in which case how does the idea that the atoms in the mirror emit a new photon jive with the FAQ's point that the electrons have discrete absorption energy states.
 
  • #5


I have other difficulties accepting the FAQ's explanation. Photons are point particles - i.e. they're infinitessimally small. Yet atoms -including atoms in a solid - are 99.9999...% empty space. The photons - most of that time - therefore should be traveling at the speed of light. Therefore, to account for the dramatic speed reduction resulting from the interaction with matter, that mass must be having a dramatic effect on the photons. What is causing that effect? Is it the EM field of the electrons? Can EM fields slow down photons traveling through a vacuum?

And again, how do we account for reflection?
 
  • #6


The photon hits a surface and its energy is asorbed and re-emmited when electrons loose energy. A photon isn't really a point particle because they have no boundaries, but that means they have no size.
 
  • #7


madmike159 said:
The photon hits a surface and its energy is asorbed and re-emmited when electrons loose energy.

Ehm...no. This is as wrong as it gets in this case. The slowing of light in a medium does NOT need absorption. Please...at least read the FAQ before answering to topics concerning the FAQ.

peter0302 said:
I have other difficulties accepting the FAQ's explanation. Photons are point particles - i.e. they're infinitessimally small. Yet atoms -including atoms in a solid - are 99.9999...% empty space. The photons - most of that time - therefore should be traveling at the speed of light.

This is very much the old fashioned Rutherford point of view. However, from a quantum point of view, you have to keep in mind, that you need wave functions to describe the situation accurately instead of point particles. The explanation cesiumfrog gave, is rather correct here.
 
  • #8


This is very much the old fashioned Rutherford point of view. However, from a quantum point of view, you have to keep in mind, that you need wave functions to describe the situation accurately instead of point particles. The explanation cesiumfrog gave, is rather correct here.
Sure, but let's say we're talking about hydrogen gas. There's always going to be 2, and only 2, electrons per molecule. The photon will interact with one, and maybe the other, and then that's it - doesn't matter what the wavefunction of those electrons is - it will have collapsed. Then there's going to be a lot of empty space before the photon reaches the next molecule.

Point being, the "delay" must be pretty huge.
 
  • #9


peter0302 said:
So if diffraction is not an atom being absorbed and reemitted, what is reflection? Is the reflected photon the _same_ photon that hit the mirror? I assume the answer is no - in which case how does the idea that the atoms in the mirror emit a new photon jive with the FAQ's point that the electrons have discrete absorption energy states.
If you are talking about reflection by a mirror, then it's metallic reflection; in this case energy states are not discrete, but continuous (conduction band).
 

FAQ: FAQ - Do Photons Move Slower in a Solid Medium?

Do photons travel at the same speed in all mediums?

No, photons do not travel at the same speed in all mediums. The speed of light in a vacuum is constant at approximately 3.00 x 10^8 meters per second, but it can be slowed down in different mediums.

Why do photons move slower in a solid medium?

Photons move slower in a solid medium because they interact with the particles in the medium. As they encounter these particles, they are absorbed and then re-emitted, which causes a delay in their movement.

How much slower do photons travel in a solid medium compared to a vacuum?

The exact amount of slowing down depends on the specific medium, but generally, photons can travel up to 30% slower in a solid medium compared to a vacuum.

Does the density of a solid medium affect the speed of photons?

Yes, the density of a solid medium can affect the speed of photons. Generally, the denser the medium, the slower the speed of light will be. This is because there are more particles for the photons to interact with, causing more delays in their movement.

Can light be completely stopped in a solid medium?

No, light cannot be completely stopped in a solid medium. However, it can be slowed down to the point where it appears to be stationary. This is known as “stopping light” and is achieved by using specialized materials and techniques.

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