How Does the Three Slit Interference Pattern Differ from the Two Slit Pattern?

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Discussion Overview

The discussion revolves around the differences in interference patterns produced by three slits compared to two slits, exploring both classical wave and quantum interpretations. Participants consider the implications of additional slits on the visibility and complexity of interference fringes, as well as the effects of varying slit thicknesses.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested
  • Conceptual clarification

Main Points Raised

  • Some participants question whether the three-slit interference pattern would show more fringes or a more pronounced pattern due to the additional light source.
  • There is a suggestion that understanding the classical wave approach is essential before delving into quantum interpretations, with some arguing that superposition applies in this context.
  • One participant proposes that the ideal three-slit pattern can be calculated easily, but acknowledges that real-world factors like slit plate leakage could complicate results.
  • Another participant raises the idea that varying the thickness of the slit plate might affect the interference pattern, prompting questions about the applicability of wave-based calculations under such conditions.
  • Some participants express differing views on whether a wave-based approach or a trajectory-based approach provides better insight into the behavior of photons in this scenario.
  • There is a contention regarding the interpretation of photon trajectories, with some arguing that assuming a trajectory adds confusion, while others suggest that pilot wave theories offer clarity.

Areas of Agreement / Disagreement

Participants do not reach a consensus on whether the wave approach or trajectory-based thinking is more useful for understanding the interference patterns. Multiple competing views remain regarding the interpretation of photon behavior and the implications of additional slits.

Contextual Notes

Participants note that the discussion involves complex interactions between classical and quantum theories, and that assumptions about photon behavior and the nature of interference patterns may vary significantly among different interpretations.

sqljunkey
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sqljunkey said:
https://www.google.com/amp/s/phys.o...sts-exotic-looped-trajectories-three-slit.amp

Based on this I was wondering how the interference pattern with three slits instead of two would look. Is there a difference; is there more interference fringes? Or does the interference pattern become more pronounced since there is more light coming from a third slit.
The answer would depend on the level at which you are actually asking the question. Before launching into the quantum nature of this, it is best to grasp fully the classical wave approach. Many threads like this one take two parallel quadrature paths with loads of misunderstandings of what people are actually saying.
They say (not surprisingly) that superposition seems to apply here - when done properly. It's a scenario that I have never thought about but it is 'reasonable'. However, it cannot be something that can be detected in everyday life because the effect would be so small and hard to detect. There must be a finite probability that photons could creep along the surface of the plate and emerge from another slit. Yet again, I look for analogous behaviour in an RF model with three radiating elements and there would be no surprise to find currents flowing across the support structure from one side to the other and radiating from other (effectively parasitic) elements. The wave approach doesn't involve the 'S shaped path' that is suggested by the diagram in the link (and I think that there may be a bit too much made of that form of interpretation) - an unspecified path for the Energy ("coupling") would suffice.
"Is there a difference; is there more interference fringes?" The ideal three slit pattern is easy to calculate. Here is a link. There are no surprises in the ideal result and it would be reasonable to add in some other contributions from small delayed contributions to the outer slit waves. That would be one step up in complexity.
Whether or not people like the wave approach to a problem like this, it will give a good indication of what to expect with a 1% leakage across the slit plate (much more than you would expect here). The patterns quoted in the paper will have been derived that way, I'm sure.
 
sophiecentaur said:
Whether or not people like the wave approach to a problem like this, it will give a good indication of what to expect with a 1% leakage across the slit plate (much more than you would expect here).
You mean something other than the wave approach would be something like this, https://en.wikipedia.org/wiki/De_Broglie–Bohm_theory ?
 
sqljunkey said:
You mean something other than the wave approach would be something like this, https://en.wikipedia.org/wiki/De_Broglie–Bohm_theory ?
All I'm saying is that a conventional wave-based calculation (with some additional contributions) will give 'an answer'. Attempts to analyse the situation based on that S shaped line in the picture can't go anywhere because that S shape is only an indicator that some energy can be considered as taking another way through the system*. The picture (as with the wiggly line in a Feynman Diagram) is not intended (imo) to be taken at face value.
*What happens if the plate is many wavelengths thick, for instance? will varying thicknesses produce different patterns?
 
sophiecentaur said:
*What happens if the plate is many wavelengths thick, for instance? will varying thicknesses produce different patterns?
Well let me ask you the same then(lol), if you vary the thickness of the plate, can you still use the same wave-based calculations to arrive at an answer?
 
sqljunkey said:
Well let me ask you the same then(lol), if you vary the thickness of the plate, can you still use the same wave-based calculations to arrive at an answer?
Why not? And you have to bear in mind that the probability calculation of 'what a photon will do' use the same maths as doing it, assuming EM waves are involved. I really don't see the objection to thinking in terms of waves whenever possible. In the case of three slits, there would seem to be (at least in principle) a way to describe how the energy is flowing in wave terms.
Nowadays (and since 'my time'), there are a number of pretty good numerical methods which give accurate predictions of how RF signals find their way around complicated antenna systems. Perhaps someone could put me right about this but any convincing argument would need to come from a pretty good level of understanding of the classical and quantum approach.
 
heh ok. Yes the wave method does give useful information. I just think that thinking about trajectories will give you more insight into what is actually happening, although this is all very questionable.
 
sqljunkey said:
I just think that thinking about trajectories will give you more insight into what is actually happening, although this is all very questionable.
Very questionable indeed. We know what a photon is doing at the moment that a dot appears on the screen - it is interacting with and being absorbed by the screen material. But thinking about what it's doing when at any other time is just going to add confusion; even the assumption that it has a trajectory to think about is wrong.
 
  • #10
Nugatory said:
But thinking about what it's doing when at any other time is just going to add confusion; even the assumption that it has a trajectory to think about is wrong.
pilot wave ideas are not so confusing. the trajectory adapts based on the system and the trajectory is known(at least to the trajectory itself). Trying and failing to measure the trajectory taken is not a theory. lul. But what do I know, this all is ludicrous.
 
  • #11
sqljunkey said:
. I just think that thinking about trajectories
Interesting concept when you consider that a photon has no actual position and that it 'experiences" no time (according to the majority opinion). You really need to be careful to avoid treating photons like little bullets.
 
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