The Debate on Light: Particle or Wave?

[futb0l]

As you all know there's been a great debate about this topic.
What does the world currently believe? and also Why?

 

[Thinkmarble]

According to quantum mechanics a photon is neither a wave nor an particle, it has some properties which can be likened under specific circumstances to the properties of the classical objects wave and it has some properties which can be likened to the properties of the classical object wave, but it also has properties which can not be explained by either.
It is best to think about photons (and everything else for that matter) a "new" kind of object.

And why does the "world" believe it ?
Simply because it works.

 

[ZapperZ]

There appears to be a strong and continuing miconception about light/photons as far as this so-called "duality" is concerned. Let's get ONE thing straight here - Quantum mechanics does NOT have two separate descriptions of light for when it behaves as a "wave" and when it behaves as "particles". PERIOD! It has one, and only one, consistent description for light, and that's that.

Now, after reading that, would one still want to consider light as having a "wave-particle duality"?

From the way I see it, the continuing misconception here is due to the ambiguity of the quality used in the question. We apply our classical ideas of what "wave" is, and what a "particle" is. A particle, like a grain of sand, has a definite boundary in space, i.e. a grain of sand doesn't appear spread out that it's exact shape and boundary are vague. Thus, it has what we classically define as a particle. A wave, on the other hand, can spread out over space.

Now, a photon, as a particle, was NEVER defined this way! A photon description in QM is NOT defined as having an exact shape and boundary in space. It is defined as clumps of energy. So in energy coordinates, it has definite "points", but it has no definite "size" in real space! This isn't your classical particle.

Having said that, the most common explanation for the "wave-particle duality" is that light behaves as waves in experiments such as the double slit, and behaves as particles when we do things like the photoelectric effect. Now, the fact that it is EASIER to describe an observation using one type of description while describing another observation using another type of description does NOT mean that they can't be described using ONE consistent discription. Most people often do not realize that one CAN describe interference effects (a typical wave phenomena) using photons![1] In fact, such technique CLEARLY explain diffraction patterns, and how the uncertainty principle is clearly at work. We don't normally subject students to such things because it is MORE involved than using the simple wave description. But we should not fool ourselves into thinking that the photon picture cannot be used to arrive at the idential phenomena that once thought can ONLY be described using the wave picture.

Again, one needs to learn QM and realize that there are no separate description for this wave-particle duality illusion. It is only a duality based on our pre-existing prejudice that something must either be a wave, or a particle. This "duality" thing only appears to be a major "issue" in pop-sci books and articles. It is a non-issue in QM texts.

Zz.

[1] T. Marcella, Eur. J. Phys., v.23, p.615 (2002).

 

[Galileo]

Light is neither a wave nor a particle.
You cannot account for certain experiments when holding on to a corpuscular interpretation of light, and the same is true for a pure wave interpretation. Instead of that the new theory which explains these phenomona with fastastic agreement is quantum theory.

Furthermore, this is not a peculiarity of light. Also electrons, neutrons and so on are neither wave nor particle. So when we refer to particles, we don`t mean anything corpuscular or wavelike, but rather a physical entity which exhibits both properties (they cannot be seperated).
I guess this is where the term 'duality' comes from. I don`t like the term since it sounds like they act like waves on a summerday and like particles when it's raining. It's simply not so. There is a unified and logical way to describe the behaviour of particles, but we must abandon the thought of it being a wave or particle.

 

[Les Sleeth]

Let's get ONE thing straight here - Quantum mechanics does NOT have two separate descriptions of light for when it behaves as a "wave" and when it behaves as "particles". PERIOD! It has one, and only one, consistent description for light, and that's that.

You seem a bit distressed to find out there are still people left who don't know everything about physics. I've thought that maybe PF should have a forum category called "Ask All the Stupid Questions You Want!" for those of us who want to understand, but don't yet and so are bound to have misconceptions.

My stupid question would be, is it possible a photon is oscillating between two conditions, one of which exhibits wave-like behavior, and the other which exhibits particle-like behavior?

 

[ZapperZ]

You seem a bit distressed to find out there are still people left who don't know everything about physics. I've thought that maybe PF should have a forum category called "Ask All the Stupid Questions You Want!" for those of us who want to understand, but don't yet and so are bound to have misconceptions.

My stupid question would be, is it possible a photon is oscillating between two conditions, one of which exhibits wave-like behavior, and the other which exhibits particle-like behavior?

Distressed??!

I'm not distressed. I had to use CAPS to make sure there is a clear emphasis on the main point of what I'm trying to get acrossed. This type of question appears repeatedly on here and elsewhere. I'm hoping that at the very least, people will pay attention to one or two sentences of what I wrote, so at least the effort I spent would not have been in vain. I have no delusion that this would stop the very same question from popping up again.

Secondly, why would a photon "oscillates" between two separate behavior when in QM, there is no separate behavior?

Zz.

 

[JohnDubYa]

Particle. No experiment has ever been performed on a photon that demonstrated wave properties to my knowledge.

 

[Les Sleeth]

This type of question appears repeatedly on here and elsewhere. I'm hoping that at the very least, people will pay attention to one or two sentences of what I wrote, so at least the effort I spent would not have been in vain. I have no delusion that this would stop the very same question from popping up again.

Logic and observation will explain why. Notice how many members we now have. In a couple of weeks, look again. More new members! A great many of them are students, ranging from grade school to graduate school. Some of us are laypersons simply interested in how the universe works. People come here excited to find an opportunity to learn, and hoping others who do know will be charitable. In an ideal world they/we might read past posts and find the answers to their questions. But that isn't nearly as much fun as having someone to personally interact with, especially if you want to ask follow-up questions. So I think part of the deal if you are going to help out at PF is patiently explaining things again and again.

In the past I've asked experts if they think it would be a good thing if everybody learned something about physics. If so, then it is obvious there are going to be different levels of understanding and interest, which means different levels of teaching and more patience (when it comes to patience, I'm not talking about enduring stubborn insistance on maintaining one's own theories, or coddling lazy minds unwilling to do a little research). I love the subject myself, but since it isn't my area of expertise, I don't have time to study it with the thoroughness required to be a physicist.

This isn't my forum, so I suppose if everyone thinks it should be sort of an exclusive club for current and future physicists, then that's that. If so, then maybe one day PF will offer a forum area called "Physics for Dummies." :tongue2:

Secondly, why would a photon "oscillates" between two separate behavior when in QM, there is no separate behavior?

Well, that's what I was asking you, the expert. You yourself said "light behaves as waves in experiments such as the double slit, and behaves as particles when we do things like the photoelectric effect." I'll try to explain what I was thinking.

My question was asking if a photon's dynamics might include a photon oscillating between being a "clump" as you say, and opening up a bit to temporarily lose its clump integrity. That might establish phases which when observed one way reveal wave-like properties, and when observed another way reveal particle-like properties.

One reason I wonder about that is because of how background radiation has "stretched" along with the expansion of the universe since the big bang (at least, according to Marcus). Obviously radiation that is more expanded now was less expanded before, so right there is the possibility that radiation is oscillating between expansion and contraction in coherence with the historical and present universe.

 

[ZapperZ]

Well, that's what I was asking you, the expert. You yourself said "light behaves as waves in experiments such as the double slit, and behaves as particles when we do things like the photoelectric effect." I'll try to explain what I was thinking.

You read wrong. What I said was...

"Having said that, the most common explanation for the "wave-particle duality" is that light behaves as waves in experiments such as the double slit, and behaves as particles when we do things like the photoelectric effect."

I said it was a "common explanation" that points to the existence of this so-called duality. But if you read the whole posting from where that came from, I insisted (repeatedly) that there is no such thing as a "duality". How can it when there is only ONE consistent description of light within QM? That was the whole point of my response. I do not know how else to make this any clearer. I have one description of light that can describe ALL the phenomena that it exhibits. So how can I answer your question anymore on the "duality" of light, when there isn't any!

Zz.

 

[Thinkmarble]

Particle. No experiment has ever been performed on a photon that demonstrated wave properties to my knowledge.

Then please explain interference effects under the assumption that photons are particles.
After you have done so explain the fact that photons have (AFAIK) a spin of 1*.

*this can actually not be explained by assuming that photons are particles or waves but rather only by assuming that they are in the new** category of quaobs (quantum objects).
There is one description (qunatum theory) which can explain all three things (photoelectric effect, interference, spin).
So saying that there are on thing ignores two third nature, saying that there is a duality leads to mushy brains and still ignores one third of nature.
**Can something be new when it is 60-70 years old ?

 

[Les Sleeth]

I do not know how else to make this any clearer.

Well, you do seem to acknowledge behavioral differences (and I am not implying behavioral differences indicate duality), and then seem to contradict yourself in the following two statements:

". . . light behaves as waves in experiments such as the double slit, and behaves as particles when we do things like the photoelectric effect."

". . . why would a photon "oscillates" between two separate behavior when in QM, there is no separate behavior?"

You read wrong. What I said was...

"Having said that, the most common explanation for the "wave-particle duality" is that light behaves as waves in experiments such as the double slit, and behaves as particles when we do things like the photoelectric effect."

I said it was a "common explanation" that points to the existence of this so-called duality. But if you read the whole posting from where that came from, I insisted (repeatedly) that there is no such thing as a "duality". How can it when there is only ONE consistent description of light within QM? That was the whole point of my response. I do not know how else to make this any clearer. I have one description of light that can describe ALL the phenomena that it exhibits. So how can I answer your question anymore on the "duality" of light, when there isn't any!.

I don't believe I did read you wrong. I don't think there is any duality, and never have. I am not confused about your explanation in the slightest, I am NOT ( ) questioning your explanation, we are not disagreeing about duality.

From your point, I lept to wondering what is happening at the quantum level that might make it appear there is duality there. My point was to ask: what is causing the different observed behaviors (i.e., double slit/photoelectric), all falling under the single reality of QM?

I asked if it might be that a photon is continously phasing in and out of particleness; or, looked at from the opposite direction, might it be continuously phasing in and out of waveness. Since we know a photon (and all particles) are intense oscillators, why couldn't a photon be something singular which simply alternates between being more "clumped" and more spread out? Might that not account for the APPEARANCE ( ) of duality? And the reason we see the differences in the double slit experiment and the photoelectric effect is because each of those processes accentuates a particular phase.

 

[ZapperZ]

Well, you do seem to acknowledge behavioral differences (and I am not implying behavioral differences indicate duality), and then seem to contradict yourself in the following two statements:

". . . light behaves as waves in experiments such as the double slit, and behaves as particles when we do things like the photoelectric effect."

". . . why would a photon "oscillates" between two separate behavior when in QM, there is no separate behavior?"

You need to read that these are observations that classically are defined to be of two different nature [I have mentioned this in the subsequent posting]. I then tried to emphasized that this is due to our prejudice from classical physics that these need to be of different nature. Nothing in QM indicates that these are of different beasts. When I can use one formulation to describe both sufficiently, then they are not "dual", they are "singular" in nature.

From your point, I lept to wondering what is happening at the quantum level that might make it appear there is duality there. My point was to ask: what is causing the different observed behaviors (i.e., double slit/photoelectric), all falling under the single reality of QM?

I asked if it might be that a photon is continously phasing in and out of particleness; or, looked at from the opposite direction, might it be continuously phasing in and out of waveness. Since we know a photon (and all particles) are intense oscillators, why couldn't a photon be something singular which simply alternates between being more "clumped" and more spread out? Might that not account for the APPEARANCE ( ) of duality? And the reason we see the differences in the double slit experiment and the photoelectric effect is because each of those processes accentuates a particular phase.

"phasing in and out" of a photon (at least a real one as opposed to a virtual one) is not described in QM, at least it is not needed to explain the photoelectric effect, Compton scattering, diffraction, and two-slit interference. Besides, why do we need to impose this phasing in and out when QM already has a statisfactory description of this?

What is often overlooked is the most important but subtle aspect of something like the 2-slit experiment. That the interference effect is NOT really an intrinsic property of the object in question (i.e. not of the photon, electron, neutron, C60 molecule, etc), but rather due to the SUPERPOSTION OF PATH! If you scale your experiment according to the object in question so that it is of the order of the deBroglie wavelength, then the object is IRRELEVANT! The superpostion of all the possible paths thru the 2-slit is what is causing the interference! The object that is passing thru the 2-slit is incidental and irrelevant once the length scale has been taken into account. Again, this is clearly described in QM, and I have cited Marcella's paper that shows this in painful detail. It is even clearer if one uses the Feynman path integral approach.

Zz.

 

[Les Sleeth]

"phasing in and out" of a photon (at least a real one as opposed to a virtual one) is not described in QM . . .

Actually I said phasing between being more spread out (wave-like) and being more "clumped" (particle-like).

 

[ZapperZ]

Actually I said phasing between being more spread out (wave-like) and being more "clumped" (particle-like).

That too.

Zz.

 

[reilly]

Not only is there duality in QM, but in classical physics as well: to wit, just think about the macroscopic treatment of alternating current. The idea of duality arose because of the apparent conflict between Thomson's particulate electron and the phenomena of electron diffraction - when such diffraction was found, it was a major mind blower. Electrons do sometimes behave as particles, sometimes as waves -- like in electron microscopes. The samething holds for light -- interference is wave-like, Compton scattering is particle like. Why deny our senses?

Certainly the background radiation observed as a relic of the Big Bang is nicely thought of as standard wave-like radiation. Bohr and his colleagues worried about this duality, and its implications for the conceptual apparatus of physics and philosophy -- tricky stuff. How coulkd this really weird stuff be?


Zz is correct in that there is a unifying perspective about all of this -- it stems from Quantum Field Theory, which easily allows both a field and a particle perspective. That is, QFT makes it possible to flip back and forth from photon states to field states all with in the same basic fornalism. But the math is highly sophisticated and formidable -- see, for example,Optical Coherence and Quantum Optics, by Mandel and Wolff, everything you wanted to know and didn't want to know about photons.

Think of duality as pragmatic -- sometimes you use your wave "glasses", sometimes your particle "glasses" to understand your measurements--you choose what works best for you. For the layman, focus on the physics, learn the history. Physics is the cumulative effort of many generations of physicists, what the old guys saw and thought is very important to understanding physics today.

Regards,
Reilly Atkinson

 

[JohnDubYa]

Then please explain interference effects under the assumption that photons are particles.

Single photons do not exhibit interference effects.

After you have done so explain the fact that photons have (AFAIK) a spin of 1*.

Is there a law of nature that particles cannot have spin?

 

[ZapperZ]

Single photons do not exhibit interference effects.

Actually John, unless I misread you, while you do need a lot of photons (or electrons or neutrons, etc) to be able to DETECT the interference effects, the interference pattern from, let's say, a typical 2-slit expt. is in fact the interference of a single photon with itself! In other words, 2-photon, 3-photon, etc interference aren't the same as single-photon interference.[1] That's why I mentioned earlier that what is significant here isn't the photon, electron, neutron, etc, but rather the superpostion of all the possible paths that ONE single object can take.

Zz.

L. Mendel, Rev. Mod. Phys., v.71, p.274 (1999).

 

[Les Sleeth]

Zz is correct in that there is a unifying perspective about all of this -- it stems from Quantum Field Theory, which easily allows both a field and a particle perspective. That is, QFT makes it possible to flip back and forth from photon states to field states all with in the same basic fornalism. But the math is highly sophisticated and formidable -- see, for example,Optical Coherence and Quantum Optics, by Mandel and Wolff, everything you wanted to know and didn't want to know about photons.

Think of duality as pragmatic -- sometimes you use your wave "glasses", sometimes your particle "glasses" to understand your measurements--you choose what works best for you. For the layman, focus on the physics, learn the history. Physics is the cumulative effort of many generations of physicists, what the old guys saw and thought is very important to understanding physics today.

Thanks Reilly, I was thinking of QFT (what little I understand about it) when I posed my question. Probably no one knows the answer to my question. It seems what we have are methods of observation, math which accounts for the behavior, but no precise explanation of exactly what is going at the quantum level on that gives the two sorts of observations.

I like the "glasses" analogy because that is related to what I am asking. I'm wondering if the two different glasses we use are like polar filters which allow only one side of a particle's two hypothetical phases (i.e., my hypothesis) to appear. Likewise, when you say "to flip back and forth from photon states to field states," it sounds like what I am envisioning.

 

[ZapperZ]

Zz is correct in that there is a unifying perspective about all of this -- it stems from Quantum Field Theory, which easily allows both a field and a particle perspective. That is, QFT makes it possible to flip back and forth from photon states to field states all with in the same basic fornalism. But the math is highly sophisticated and formidable -- see, for example,Optical Coherence and Quantum Optics, by Mandel and Wolff, everything you wanted to know and didn't want to know about photons.

I think I know what you are getting at here. Unfortunately, as you can see from the previous post, it can easily be misinterpreted or misrepresented. The biggest obstacle in this issue is trying to convey the meaning of the mathematics. QFT (and QED) makes NO provision for classical fields. Therefore, classical fields (and thus, "waves") essentially do not exist and are meaningless in QFT.

Then what are we left with? I hate to say we have a "particle field", because that again can be misinterpreted (refer to my discussion what classical particle is and why this is NOT what a photon is). Can I get away with saying a "quantum field" without grossly misrepresenting the mathematics? Maybe. If we stick by that, then I would not want to leave the impression that photons can flip back and forth between two apparently different perpective.

Zz.

 

[ZapperZ]

I realize the burden is on me to make myself clear, and I haven't yet (and believe me, I am completely ready to accept that my idea is 100% wrong as soon as I can tell someone is responding to what I am saying).

I do NOT mean a photon "can" flip back and forth between "perspectives." I emphasize your use of the word "can" because what I am suggesting is that a photon must flip back and forth because that is part of what defines what it is. I am saying, or asking: what if a photon is rapidly (really rapidly) shifting between opening out and tightening back up? In fact, shifting so fast that both phases exist simultaneously, and would appear to exist simultaneously if we could observe the phases at the same time. That leads to the second concept of observation, which is that the methods we employ expose either one side of the shift or the other, depending on the method we use. I've included two little diagrams to explain my meaning.

In Diagram 1 is a platform which swings from side to side. The top figure represents when the platform is at the far left extreme, and the bottom figure represents when the platform is at the right extreme.

Diagram 2 represents what should happen if we could get the platform to oscillate between the two extremes fast enough. At some critical speed, the platform would appear to exist simultaneously in both the left and right positions, differentiating into left and right "phases."

That analogy might demonstrate simultaneity and phase differentiation, but it isn't the best analogy for explaining what happens on the human observational end (because the two phases are so similar). But say I had a device that only registered things angled to the left of it, and another device which only measured things angled to the right of it. Whichever one I rely on one to observe, automatically prevents me from seeing the other phase, which is still there counterbalancing its sister phase whether we can observe it or not. So, it isn't a matter of a photon "can" flip, or a photon's flip in "perspective."

I'm sorry, but I was under the impresson that you were asking for what we already know about photons and how they are described within the theory that works. I did not realize you were trying to offer an EXPLANATION for why they work, which isn't contained in the theory. I thought such things are usually confined to the Theory Development section and I typically do not wish to entertain such querries.

Zz.

 

[Les Sleeth]

I'm sorry, but I was under the impresson that you were asking for what we already know about photons and how they are described within the theory that works. I did not realize you were trying to offer an EXPLANATION for why they work, which isn't contained in the theory. I thought such things are usually confined to the Theory Development section and I typically do not wish to entertain such querries.

Actually I was trying to find out if anyone (physicists I mean) is thinking this way, or is investigating this possibility. I thought I'd read something about QFT in Scientific American which hinted at this (at least, that's what I took from the article). But I do realize that for some, EXPLANATIONS can be really freaky, nerve wracking and downright ruinous to one's day. :rolleyes

On second thought, maybe you are right. I'll delete that that question here and move it to theory development while I see if I can find the SA article.

 

[rayjohn01]

Duallity

I agree with Zapper that QM provides a single description , but I do not think that it provides a 'seeable' one , and I think an experiment often emphasizes one characteristic over another.
Think of a bird chirp , you can examine it in time and you can look at it in frequency but these views seem mutually exclusive in anyone experiment.
In fact the ordinary classical 'fourier transform' can be used to estimate Planks constant 'h'.
I also agree that the assumption behind interference ( two slit or otherwise) is that of single photon self interference , but QM deals with that by disolving the object into a many paths 'quasi reality' which is a mathematical formalism and in my view rather difficult to truly visualize.
As for oscillations -- okay as a thought -- bit like neutrinos , but does not appear necessary in a workable theory at present.
Ray.

 

[ZapperZ]

I agree with Zapper that QM provides a single description , but I do not think that it provides a 'seeable' one , and I think an experiment often emphasizes one characteristic over another.

But I think that in many (all?) cases, it is because we have it ingrained in our view that 'wave-like" and "particle-like" are mutually exclusive and cannot be explained using one formalism. If one were to be born in a quantum universe and then later on learn about classical mechanics, I would suspect that one would look at the dichotomy of "wave" and "particle" to be rather strange, arbitrary, and artificial. The fact that all the so-called wave-like and particle-like properties can be explained using a single, coherent photon description is the clearest and strongest point that I can think of in favor of this argument. Just because things appear to look that they came from different phenomena does not mean they are different. Classical celestial mechanics and the mechanics of bridge building may appear to be different, but we all know they are governed by the same set of descriptions. No one would say that these are two different phenomena.

Zz.

 

[terrabyte]

last thing i read about photons was they they are "particles" in the basic sense, and they exhibit wave properties because if their unique property of being first state energy.

their diffraction is not actually bending of the light, but rather the light hitting something and transfering its energy to it, and in turn that something jumps back down from its excited state and re-emits the light in a direction seen as "bent"

frequency and wavelength of particle light can be defined as particles per second.

forgot where the heck i read this at though, but it seems sound

 

[ZapperZ]

last thing i read about photons was they they are "particles" in the basic sense, and they exhibit wave properties because if their unique property of being first state energy.

their diffraction is not actually bending of the light, but rather the light hitting something and transfering its energy to it, and in turn that something jumps back down from its excited state and re-emits the light in a direction seen as "bent"

frequency and wavelength of particle light can be defined as particles per second.

forgot where the heck i read this at though, but it seems sound

I did plan on stopping my involvement in this string, but I think I still need to make more things are straighten out.

In a string a few weeks back related to a question on the uncertainty principle, I brought up the issue that one of the clearest demonstration of this principle is in fact something we observe very easily - the diffraction effect of light. Classically, we attribute this to an intrinsic wave property, but really, if you look at it closely, it is actually an in-your-face demonstration of the uncertainty principle. Let me explain...

Let's say you have a single slit alligned along the x-axis, so that the width d of the slit is along the y-axis. A monochromatic light is propagating along the z-axis and hits the single slit. At a distance after the slit is a screen, potosensitve paper, etc, etc, to record when a photon hits that location.

Now let's say that the slit is open wide (i.e. d is much greater than the wavelength of the light). What you end up with on the screen is essentially the very same image of the slit, i.e. very little diffraction at all.

OK, next, you make the slit very small (d is comparable to the wavelength of the light). Now it gets interesting. You lose the shape of the slit, and now you get the Fraunhoffer pattern. You have a smearing of intensities in which the width of the 0th order pattern is LARGER than the width of the slit itself. In fact, the smaller the slit width is, the wider the 0th order smear.

There's nothing surprising (I hope) in what I've just described. What a lot of people do not realize that this is a direct manifestation of the uncertainty principle.

Let's look at the first instance when d >> wavelength. And let's say I have very weak source in which on average one photon are impinging on the slit at any given instant. Since d is large, the uncertainy in the location of this photon when it hits slit is also large. In fact, Delta(y) is of the order of the width of the slit d. If I want to know it's corresponding momentum in the y direction (i.e. p_y), then I look at where it impacted on the screen, and then using baby kinematics and geometry, I can find p_y.To get the spread in p_y, I will have to collect this info for many photons passing through the slit. This will give me Delta(p_y).

Now what happens when d<<wavelength? As the slit is made thinner, I know with increasing accuracy where a y-position of the photon is that passes through the slit. Thus, the uncertainy in the position of each photon that passes through the slit is not worse than the width of the slit, i.e. Delta(y) ~ d, and this is getting smaller and smaller, meaning I know more about where along y the photon was when it when through the slit.

If I try to measure its momentum, something interesting happens. One photon may hit the screen right in the same y-location as the slit, but another one will hit it way off the slit. Another one hits on the other side of the y-location, etc... in other words, as I collect more and more of photon impact on the screen, the photons seems to have a larger spread of p_y after they pass the slit! This is what will eventually form the wide 0th order diffraction pattern! The smaller the slit (the better I know the location of the photon the moment it passes through the slit), the wider the distribution of the momentum along the very same direction. You cannot predict with as good of an accuracy as in the first case the momentum of the next photon that will pass through the slit.

This is a rather long (and maybe even confusing) demonstration of the uncertainty principle. However, if you have read this far, I hope that it accomplishes two things: (i) that you realize that the photon picture CAN in fact describes what we used to think to be only something that can be explained by waves, and (ii) that you now understand how uncertainty principle works and how "obvious" it is in some cases.

Now I need to rest my fingers...

Zz.

 

[terrabyte]

does the same thing hold for laser light traveling through a slit?

 

[terrabyte]

in the model i described, diffraction is wholly based upon photon-energy interaction with the material you make the slit out of.

with a large slit, more light goes through that doesn't contact the material, and generally drowns out the effects of the light that does hit the material edges. as the slit gets smaller, that light that doesn't contact the edges of the material gets smaller, and the difracted light (photons hitting the edges of the material) becomes more apparant.

as described, the photons hit the edges and get absorbed kicking the atoms up to a higher energy state. the atoms then drop back to their natural state and emit the light in a random direction. this randomness is the dispersion we witness from the ultra thin slit.

i'm thinking that this also ties somehow into your "uncertainty principle"

 

[ZapperZ]

in the model i described, diffraction is wholly based upon photon-energy interaction with the material you make the slit out of.

with a large slit, more light goes through that doesn't contact the material, and generally drowns out the effects of the light that does hit the material edges. as the slit gets smaller, that light that doesn't contact the edges of the material gets smaller, and the difracted light (photons hitting the edges of the material) becomes more apparant.

as described, the photons hit the edges and get absorbed kicking the atoms up to a higher energy state. the atoms then drop back to their natural state and emit the light in a random direction. this randomness is the dispersion we witness from the ultra thin slit.

i'm thinking that this also ties somehow into your "uncertainty principle"

It doesn't. Think about it. If you have a uniform density of photons per unit cross-sectional area, it means that roughly the same number of photons are "interacting" with the edge of the slit, no matter how large or how thin you make the slit. The photons that are not in the layer in contact with the slit doesn't really care where the edge of the slit is. So if we buy your scenario, the diffraction pattern should occur no matter what the size is.

Furthermore, the model of a beam of object scattering off the edge of an opening has a very different distribution than a diffraction pattern. You end up with something that looks like a gaussian distribution centered at the middle of the slit. This is certainly NOT the fraunhoffer pattern that is seen in a diffraction.

I need to point out that what I described isn't MY theory, nor something I dreamt up. It is out of QM itself. Anyone is welcome to pick up a QM text and verify it him/herself. It certainly isn't "my" uncertainty principle.

Zz.

 

[terrabyte]

i said the diffraction does occur regardless of the slit size, but with a larger size the volume of light that doesn't come in contact with the slit sides is greater and that light drowns out the pattern so it's hard to detect it.

gonna see if i can find the text i read this from... although it probably was a good 10 years ago :|

 

[ZapperZ]

i said the diffraction does occur regardless of the slit size, but with a larger size the volume of light that doesn't come in contact with the slit sides is greater and that light drowns out the pattern so it's hard to detect it.|

That doesn't make sense. The photons that do not come in contact with the slit edge will just go through unscatterned. The ones that do will (if your model is correct), be scattered via large angles away from the axis of the slit (i.e. at very large y values in my earlier axis orientation). So how could the one that are not scattered "drowns out" the one that are scattered way off the center of the slit? You do know that the 0th order diffraction pattern can be way wider than the size of the slit itself, don't you? So the one that get deflected, say, 20 degrees from normal... how does that get drowned out as you make the slit wider?

Zz.

 

[terrabyte]

the ones hitting the left side of the slit scatter to the right and have to travel through the flow of the main stream. the ones on the right scatter to the left and similarly have to travel through the stream.

the ones that hit the left and scatter MORE to the left are very faint <very small number of TRUE edge particles that can shoot that angle without hitting another material atom.

what happens when the slit is made extremely narrow is that noise that drowns out the particles from left to right and right to left is reduced enough to where we can view the scattering effects easily.

i really do need to find the text i read... it had diagrams and stuff

 

[terrabyte]

this page gets into it a little as far as photon-atom interactions

Link to crack pot site deleted


gonna have to hunt down more stuff later, must... sleep

I suggest careful reading of ZapperZ's posts, much more reliable then random web searchs.

Integral

 

[ZapperZ]

this page gets into it a little as far as photon-atom interactions

Removed link
Integral
gonna have to hunt down more stuff later, must... sleep

Yikes! You should learn to read established physics journals and texts, and not someone's personal website. I hate to think that you based your physics knowledge on something like this! If you really want to screw up your understanding of physics, then go to Crank Dot Net. You'll find enough "ideas" to even contradict what you read on that site. So then you will be left with the delima of which quack to believe in.

Secondly, it appears that when I said that even if the scattering off the edge of slit model is correct, you would only get something resembling a gaussian distribution of intensities behind the slit, this seems to have not made any impression on you. Keep in mind what a "gaussian distribution" looks like, and what an actual diffraction pattern looks like. You'll notice why those two are not compatible.

Thirdly, and this is the most imporant error in your whole model, is that you seem to not know that the scattering probabilty between two photons are unbelievably small. In the visible range, it is almost non-existent. Instead, we have a SUPERPOSTION of light - they passed though each other "unharmed". Thus, your argument that a large slit will cause more of the "scattered" photons to get washed out doesn't hold water. And we haven't talked about the validity of photons "scattering" off an opaque material that make up a slit.

Zz.

 

[jatin9_99]

light has both the nature of wave and particle, as according to de broglie he showed his work as folllowing

Einstein said e=mc^2 so this is particle nature

and max Planck said h=wc where w is wavelenght and c speed of light
=> c=h/w
and e=mc^2
=> e=m(h/w)^2
this proves that light have wave nature too

 

[ZapperZ]

light has both the nature of wave and particle, as according to de broglie he showed his work as folllowing

Einstein said e=mc^2 so this is particle nature

and max Planck said h=wc where w is wavelenght and c speed of light
=> c=h/w
and e=mc^2
=> e=m(h/w)^2
this proves that light have wave nature too

Ok, now see what I mean? It is as if all the things that have been discussed here on this string didn't exist!

And before someone tells me not to pop a blood vessel or something over this, let me just say that I'm not "distressed". I'm just disappointed that I wasted all that effort for nothing. Even after spending more than 10 years on the 'net participating in discussion forums such as this, it still doesn't lessen the disappointment whenever something like this occurs.

Zz.