What happens to light after interference?

In summary, the conversation discusses the interference of two beams of light and the potential changes to the properties of the beam if it passes through an overlap region with another beam. The conversation also mentions the possibility of photon-photon interactions and the negligible impact it would have on the overall results. Ultimately, it is concluded that for practical purposes, the beam would emerge with the same properties as if there was no overlap region.
  • #1
Dadface
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Imagine a beam of light diverging from a source and being incident on a detector. Now imagine a similar set up but with one main difference. The difference is that on its journey to the detector the beam passes through a second beam such that in the overlap region the two beams interfere. Having passed through the overlap region the beam is then incident on the detector.
My question is, if everything else apart from the prescence of the second beam is kept the same are there any differences in what can be detected?
As far as I know at present all similar detectors would record the same results. Having passed through the overlap region the beam would emerge with the same properties as it would have if there was no overlap region. Is that correct? I will be very grateful if anyone can confirm or clarify. Thank you.
 
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  • #2
Dadface said:
The difference is that on its journey to the detector the beam passes through a second beam such that in the overlap region the two beams interfere.

first of all if the beam passed over other beam, both are coherent then only interference can be observed.. if the two beams which are overlapped are from different sources then there will be no interference and there will be no change what the detector will detect otherwise.

If the 2 beams are from same source and in phase with each other then the fringes (dark and bright) can be detected...
 
  • #3
As we know a beam of light is made up of photons. In classical electrodynamics the Maxwell equations are linear and therefore they cannot describe any photon-photon interaction. In the visible region (photon energies of the order of a few eV) photon-photon is negligible. For gamma rays with photon energies of the order of 500 MeV a pair of photons can annihilate creating an electron-positron pair with a substantial probability. Thus, it depends on what source of beam you use.
 
  • #4
Mohammad Hadi said:
first of all if the beam passed over other beam, both are coherent then only interference can be observed.. if the two beams which are overlapped are from different sources then there will be no interference and there will be no change what the detector will detect otherwise.

If the 2 beams are from same source and in phase with each other then the fringes (dark and bright) can be detected...

I think you just couldn't grasp his question. He is not asking what it is going to be appeared in the overlapped region rather he would want to know how the interaction could change the properties of the first beam having passed through the overlapped region and being incident on the same detector.
 
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  • #5
Hi Mohammad. As PaulDirac pointed out I want to know what observed changes are there, if any, after the beams have passed through each other. Thanks for replying.

Hi PaulDirac. Yes, I forgot about pair production. I didn't know what to google in order to search this topic but your post suggests that "photon photon interactions" might give some useful information. I will try it later. Thank you.
 
  • #6
Dadface said:
As far as I know at present all similar detectors would record the same results. Having passed through the overlap region the beam would emerge with the same properties as it would have if there was no overlap region. Is that correct?

For all practical purposes, yes. Light meeting light is a lot like what happens when you drop two stones into a body of still water - the ripples spread out in rings, and where they meet they pass through each other and continue undisturbed.
 
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  • #7
Dadface said:
Hi Mohammad. As PaulDirac pointed out I want to know what observed changes are there, if any, after the beams have passed through each other. Thanks for replying.

Hi PaulDirac. Yes, I forgot about pair production. I didn't know what to google in order to search this topic but your post suggests that "photon photon interactions" might give some useful information. I will try it later. Thank you.
Another term is "two photon physics". Note that the cross section is very small for this interaction, so the change to the beam is very small.
 
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  • #8
Thanks Nugatory and DaleSpam my question has been answered.
 

Related to What happens to light after interference?

1. What is interference of light?

Interference of light refers to the phenomenon where two or more light waves interact with each other and either reinforce or cancel each other out. This results in the formation of a new wave with a different amplitude, wavelength, or direction.

2. How does interference affect light?

Interference can cause changes in the properties of light, such as its intensity, polarization, or direction of propagation. It can also lead to the formation of distinct patterns, such as interference fringes, which can be observed in interference experiments.

3. What happens to the light waves after interference?

After interference, the light waves continue to travel in their respective directions with their altered properties. The resulting wave is a combination of the two interfering waves and can exhibit constructive or destructive interference, depending on the phase difference between the two waves.

4. Can interference of light be observed in everyday life?

Yes, interference of light can be observed in various natural phenomena, such as soap bubbles, oil slicks, or the colors in a peacock's feather. It is also utilized in technology, such as in the production of holograms and in optical coatings for lenses and mirrors.

5. How is interference of light used in scientific research?

Interference of light is a fundamental principle in the study of optics and is used in various scientific research fields, such as astronomy, microscopy, and spectroscopy. It allows scientists to study the properties of light and its interactions with matter, leading to advancements in our understanding of the universe and the development of new technologies.

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