Can A White Photon Exist?not so easy to Answer

  • Thread starter chemistryknight
  • Start date
  • Tags
    Photon
In summary, White light is composed of different colors of light. When looking at a white light source, you would see photons of all different colors, as all those colors combined create the color white as seen by the human eye. However, there is no "white" photon, as all photons are diffracted to the same spot.
  • #71
ZapperZ said:
WHOA! No! THIS is exactly what I want you to show! What system produces ONE photon with such superposition! You cannot "say" this if you can't demonstrate that this thing actually exist.

[the rest of your posting is moot if this doesn't exist].



You mean the H atom transition from 2p to 1s isn't good enough? Or do you think this isn't possible or isn't a realistic example?

Zz.

I also don't know how to produce this state.
:tongue:
Ask vanesch, :biggrin: , he introduced this state.
But WHY exactly can't this state exist, besides that we both don't know how to produce it.
In the prism example I get the same experimental results, both in the 'statistical mixture' AND in the 'superposition' interpretation.

What I mean is: suppose a theoretical physicist claims that there is such a one-photon-superposition state. He would say something like:
"Hey, I interpret the spectrum behind the prism in another way.
It could also be that this is caused by many photons, each of them in a superposition state."

Then how would you disprove his claim experimentally (e.g. by another experiment)?
 
Physics news on Phys.org
  • #72
Edgardo said:
What I mean is: suppose a theoretical physicist claims that there is such a one-photon-superposition state. He would say something like:
"Hey, I interpret the spectrum behind the prism in another way.
It could also be that this is caused by many photons, each of them in a superposition state."

Then how would you disprove his claim experimentally (e.g. by another experiment)?

You are forgetting the SOURCE of the light that is making this spectrum. Let's look at an incandescant light bulb, for instance. The source of light is the heating of tungsten. As with thermionic electron emission, heating produces a large spectrum of vibrational states. EACH of these states produces a unique transition. So what you get is a lot of photons, each having a unique energy. It is NOT a bunch of photons, each having a superposition of all of these vibrational states. You NEVER hear people analyzing spectra and ever consider such superposition.

As vanesh has mentioned, you cannot deduce superposition this way AFTER an actual measurement of the superposition. The ONLY way to prove such a thing occurs is to make a measurement of a non-commuting observable that does not collapse the superposition. We have seen this in H2 molecules, NH3 molecules, and in SQUID experiments on a superconductor junction. If you think an individual photon can have such superposition, then it is incumbent upon YOU to show evidence of this. A prism and spectral analysis can ONLY tell you that you have a photon with this freq, another photon with another freq., another photon with that freq... Nowhere in the measurement can you ever deduce that it was a photon having a superposition of energy that decided to collapse upon measurement into that particular energy or freq. If you (or that theorist) can make such definitive deduction of superposition based simply on that, then you have drawn conclusions beyond what the results have revealed. As an experimentalist, I am never comfortable with doing such things. Maybe you have a different standard.

Zz.
 
  • #73
ZapperZ said:
If you think an individual photon can have such superposition, then it is incumbent upon YOU to show evidence of this.

Well, I reiterate that a femtosecond laser pulse needs such kinds of superpositions. The difficulty is that it is the source, and not the measurement apparatus. I don't know of a femtosecond photomultiplier, so all "position measurement" (with light, this comes down to "time measurement") apparatus is so terribly slow that it is always compatible with almost pure momentum states. But at least we have the *source* (nl. a laser).
If it were a mixture of "pure-energy" photons, you could never obtain a structure in time (or position) which is so lumped.

cheers,
Patrick.
 
  • #74
vanesch said:
Well, I reiterate that a femtosecond laser pulse needs such kinds of superpositions. The difficulty is that it is the source, and not the measurement apparatus. I don't know of a femtosecond photomultiplier, so all "position measurement" (with light, this comes down to "time measurement") apparatus is so terribly slow that it is always compatible with almost pure momentum states. But at least we have the *source* (nl. a laser).
If it were a mixture of "pure-energy" photons, you could never obtain a structure in time (or position) which is so lumped.

cheers,
Patrick.

I don't see how a fs laser "pulse" would produce a superpostion on each individual photon in that pulse. The pulse itself WILL of course consist of possible superposition of various wavelength to make a pulse, but within that pulse, it consists of a gazillion photons, each having a different wavelength.

Again, I deal with laser pulses of about 8 ps in length. We have to produce such pulses not simply by opening and closing shutters (because that will definitely generate a lot of harmonics in the pulse), but using a complicated set of pockel cells, mirrors, etc. in our REGEN simply to do pulse shaping. This is to minimize the presence of photons with energies not within what we want. At no time do we consider the idea of an individual photon within such a pulse having "superposition" of all the various harmonics that together make up the pulse.

So again, I still do not see an experiment/measurement that shows the existence of such a superposition on an INDIVIDUAL photon.

Zz.
 
  • #75
ZapperZ said:
I don't see how a fs laser "pulse" would produce a superpostion on each individual photon in that pulse. The pulse itself WILL of course consist of possible superposition of various wavelength to make a pulse, but within that pulse, it consists of a gazillion photons, each having a different wavelength.

So you consider such a pulse as a statistical mixture of "single energy photons". But I'm now claiming that a photon of fixed energy cannot be localised in space, so you cannot have such a mixture of which all of them arrive "in time". If it were such a mixture, the probability of detecting them should be independent of the phase with the "lock-in" signal and you'd get a more or less continuous arrival of all the different photons. And IF you filter them in energy, so as to FORCE them into a mixture, then you will get a loss in position (timing) resolution which is corresponding to the energy resolution by which you selected them (and thus truncated the bandwidth over which they could have a superposition).
In fact, it is silly to have a pulsed laser, followed by a very narrow bandwidth filter ! You can then just as well take an incandescent bulb and illuminate the filter :smile: You've lost the coherence, and you also loose the time structure. (exactly because you've transformed an interesting superposition into an uninteresting mixture).
But a picosecond isn't yet fast enough: you can easily have a delta lambda / lambda = 10^(-3) and still have picosecond pulses at optical frequencies. So this looks like "reasonably fixed energy" and "pulsed". In order to get dramatic effects of superposition with optical frequency, you need to go to femtosecond lasers. If you then see that they have amazing bandwidths, all of the above takes on much more meaning.

cheers,
patrick.
 
  • #76
vanesch said:
So you consider such a pulse as a statistical mixture of "single energy photons". But I'm now claiming that a photon of fixed energy cannot be localised in space, so you cannot have such a mixture of which all of them arrive "in time".

Not if they're coherent with each other. We know this can happen because the very same thing is going on in a superconductor - the coherent superposition of a number of "plane waves". Each one of them are not localized, which is the very explanation for its zero resistance. yet, due to coherence, they can all "arrive in time", as we can see in any SQUID measurement.

Thus, just because they are extended in space does not negate them forming coherent pulses. There are preceedent for such things already.

Zz.
 
  • #77
To some degree, the issue of a white photon is a matter of definition. To wit, see the discussion in Mandel and Wolf, Optical Coherence and Quantum Optics (p 480) on localized photons, which they describe by a Gaussian superposition of individual photon momentum/helicity states. Think about one-photon-at-a-time with such a state vector -- over time and many measurements, the location of the photon will be well defined by the mean of the location measurements, and the spread will be proportional to the standard deviation -- pretty much the same idea as a sequence of one photon double slit interference experiments.

So it is perfectly reasonable to define a white light state for a photon as an equally weighted state of optical frequencies. With a very faint source, you will see little if anything. Increase the strength of the source, and you will begin to see white light. What you would see with less than full intensity is very dependent on the optical processing capabilities of your eyes and brain -- perhaps there are conditions in which you would see shifting colors.

If you want to get a sense of this white photon triggering several rods/cones, think of low energy Compton scattering of of three relatively localised electrons, or of multiple photoelectric hits -- with an incident white photon. The probability of anything but the standard processes, that is simultaneous "hits" will be very small-for one incident photon. With many, the situation does indeed change. But not to worry.

To see white light requires quite a few white noise photons.

Mandel and Wolf go over every inch of photon physics -- lasers to thermal sources, coherent fields, light amplifiers, nonlinear effects, and on and on -- in about 1200 pages. So, if you want to understand photon physics, read Mandel and Wolf. Such a read will resolve most of the issues discussed in this thread.

Regards,
Reilly Atkinson
 
  • #78
Hi all,

I thought about a photon that could be in a superposition
of energy-states. And maybe the COMPTON-SCATTERING might
be such a superposition state.

Right after the scattering of the photon, we don't know it's energy,
so I could describe it by a superposition.

What do you think of it?

-Edgardo
 
  • #79
ZapperZ said:
Not if they're coherent with each other. We know this can happen because the very same thing is going on in a superconductor - the coherent superposition of a number of "plane waves". Each one of them are not localized, which is the very explanation for its zero resistance. yet, due to coherence, they can all "arrive in time", as we can see in any SQUID measurement.

But again, what ELSE is this "coherent superposition of plane waves" but a superposition of momentum states ?

Remember that there is NO phase relationship between the individual "quantum waves" (quantum states) in a MIXTURE, and that there IS a definite phase relationship in a SUPERPOSITION. This is in fact the essential difference between a mixture and a superposition. So if you talk about the COHERENT (= phase related) superposition of plane waves, you're talking about a superposition of quantum states, and not about a statistical mixture.

You seem to think that photon number 1 is in a plane wave state with momentum k1 and phase 36 degrees, photon number is in a plane wave state with momentum k2 and phase 42 degrees etc...
But this is not a possible state description in quantum mechanics ! Phase relations only make sense between components of a same state.

You cannot write a mixture of 2 photons as:
state of photon 1 is |k1>
state of photon 2 is exp(i alpha) |k2>
on which you will successively apply a measurement.

Well, you can write it, but it is exactly the same physical situation as:
state of photon 1 is |k1>
state of photon 2 is |k2>

That is because |k2> and exp(i alpha) |k2> describe the same ray in Hilbert space (and each ray corresponds to a unique physical state).

So you cannot COHERENTLY talk about these two states, or "waves" (in the position basis). There is no way to fix any phase relationship between components of a mixture.

The only, very only way to do this is to say that you have prepared the system twice in a single-photon state, described by:

|k1> + exp(i alpha) |k2>

In this case, the exp(i alpha) is NOT arbitrary, and this is the entire meaning of coherence. The "wave" in the position basis is then indeed, the Fourier composition of the two plane waves (with wave vectors k1 and k2) and with a phase relationship alpha.

cheers,
Patrick.
 
  • #80
vanesch said:
But again, what ELSE is this "coherent superposition of plane waves" but a superposition of momentum states ?

But why is this an issue? Have I ever mentioned that such a thing isn't possible? I don't believe this is the source of this discussion.

The issue here has always been the confusion when we use these things to describe (i) an individual photon and (ii) a "pulse" that contains a gazillion photons. I have never (and in fact I have already mentioned it) said that a pulse of light does not contain a superposition of various freq. This is a fact that one can obtain simply via doing a Fourier transform of that pulse. However, this is not a single, individual photon.

Again, taking the lessons from superconductivity, coherency isn't just due to the fact that we describe things via plane-wave states. They become "locked" in step due to some "external" mechanism. For cooper pairs, it's the condensation. For photons, it is due to the source (or the downstream optics, etc). So coherency isn't an automatic property of plane-wave states, but can initiated externally. This is what I was trying to answer to your previous assertion that if plane wave states aren't localized, how can they "in time".

At some point in this thread, there appears to be a switching back and forth between the Fourier superposition of waves, and the quantum superposition of states. I do not see that one automatically implies the other.

But let's go back to the original assertion. If I interpret it correctly, you are saying that if we have a white photon, then I can write this photon as (crudely)

|w> = a1|v> + a2|i> + a3|b> + a4|g> + a5|y> + a6|o> + a7|r>

If I make an observation using my eyes, unless you are claiming that our optical system can view a superposition of all these states (very much similar to the bonding-antibonding states of H2), then even you have stated that you will simply collapse the superposition and view only one of these.

If what I have said is true, then we are left with only 2 issues:

1. There are NO "white photons" within the context that it has never been observed, measured, detected, etc. by our eyes. After all the term "white" is a human optical quality.

2. Detection measurements we have of photons (be it energy, momentum, wavelength, freq., etc) have not detected the presence of |w> states superposition. All experiements using photons have yielded them to be in a definite state and not a superposition of them. Only a repeated measurement of an identical system will yield the HUP relationship between two non-commuting observable.

So which part of any of the above do you disagree?
 
  • #81
ZapperZ said:
At some point in this thread, there appears to be a switching back and forth between the Fourier superposition of waves, and the quantum superposition of states. I do not see that one automatically implies the other.

??

Then what is the quantum-mechanical description, according to you, of "a Fourier superposition of waves" ? No classical-QM switching back and forth allowed, only Fock states (which, according to QED, completely describe all possible pure states of the EM field).


But let's go back to the original assertion. If I interpret it correctly, you are saying that if we have a white photon, then I can write this photon as (crudely)

|w> = a1|v> + a2|i> + a3|b> + a4|g> + a5|y> + a6|o> + a7|r>

If I make an observation using my eyes, unless you are claiming that our optical system can view a superposition of all these states (very much similar to the bonding-antibonding states of H2), then even you have stated that you will simply collapse the superposition and view only one of these.

Of course. That's what I said: if you do an energy measurement, of course you will only find one definite result for one photon. But that doesn't mean that the photon was in such a state BEFORE the measurement. So an energy measurement is the worst kind of measurement one can think off to try to show the existence of the |w> state!
But what you are saying amounts to the following: "Because I only have a vertical and horizontal polarizer, light can only be vertically or horizontally polarized. It cannot be 45 degree polarized ; that just consists of a mixture of purely vertically and purely horizontally polarized photons."
If I see half of my light intensity get through my vertical polarizer, and half of my intensity get through half of my horizontal polarizer, that means that 50% of those photons are vertically polarized, and 50% are horizontally polarized.
Then I come in and I say: no, you have two possibilities.
The case you cite (a statistical mixture) IS a possibility. But your light could also be 45 degree polarized. And you come back and tell me that light, by definition, can only be vertically or horizontally polarized, look, when I use vertical and horizontal polarizers I always get ONE PRECISE ANSWER for each of them. So what's that silly business of *superpositions of polarization* ?? Only horizontal or vertical, look at my results !
But then I say: well, I can make the difference between the 50-50 HV mixture, and the 45 degree case, by having a 45 degree and a 135 degree polarizer: your mixture gets through those just as well 50/50, while the 45 degree polarization gets through the first 100% and is fully blocked by the second. So the worst possible measurement to distinguish between a mixture HV and 45 degree pure are HV polarizers of course !

In my example, there is an analogy between HV polarization and momentum states, and 45 / 135 degree polarization and position states.

If what I have said is true, then we are left with only 2 issues:

1. There are NO "white photons" within the context that it has never been observed, measured, detected, etc. by our eyes. After all the term "white" is a human optical quality.

2. Detection measurements we have of photons (be it energy, momentum, wavelength, freq., etc) have not detected the presence of |w> states superposition. All experiements using photons have yielded them to be in a definite state and not a superposition of them. Only a repeated measurement of an identical system will yield the HUP relationship between two non-commuting observable.

So which part of any of the above do you disagree?

Obviously I disagree with 1, and 2 is trivial because it is not the appropriate measurement to detect such a superposition.

cheers,
patrick.
 
  • #82
vanesch said:
?? Of course. That's what I said: if you do an energy measurement, of course you will only find one definite result for one photon. But that doesn't mean that the photon was in such a state BEFORE the measurement. So an energy measurement is the worst kind of measurement one can think off to try to show the existence of the |w> state!
But what you are saying amounts to the following: "Because I only have a vertical and horizontal polarizer, light can only be vertically or horizontally polarized. It cannot be 45 degree polarized ; that just consists of a mixture of purely vertically and purely horizontally polarized photons."
If I see half of my light intensity get through my vertical polarizer, and half of my intensity get through half of my horizontal polarizer, that means that 50% of those photons are vertically polarized, and 50% are horizontally polarized.
Then I come in and I say: no, you have two possibilities.
The case you cite (a statistical mixture) IS a possibility. But your light could also be 45 degree polarized. And you come back and tell me that light, by definition, can only be vertically or horizontally polarized, look, when I use vertical and horizontal polarizers I always get ONE PRECISE ANSWER for each of them. So what's that silly business of *superpositions of polarization* ?? Only horizontal or vertical, look at my results !
But then I say: well, I can make the difference between the 50-50 HV mixture, and the 45 degree case, by having a 45 degree and a 135 degree polarizer: your mixture gets through those just as well 50/50, while the 45 degree polarization gets through the first 100% and is fully blocked by the second. So the worst possible measurement to distinguish between a mixture HV and 45 degree pure are HV polarizers of course !

But...but... don't you see? THIS is the VERY type of measurement that I've been asking for to show the existence of superposition of energy states in an individual photon! I am CONVINCED that a photon can exist in a superposition of what you call "polarization". You got no arguments from me there! The experiment you described is VERY convincing in showing that. What I asked is something in the same, analogous form to show the same effect for a photon! We can't just say "well, since superpostion can occur for that observable, then it makes sense that it should be possible for OTHER observables". This is simply not true since this is very system-dependent. Just becaue an electron can be in superpostion of spin, doesn't mean its charge must also be in such a state. So far, the arguments that superpostion of energy/wavelength/freq/ for an individual photons have been built via that line.

Zz.
 
  • #83
ZapperZ said:
We can't just say "well, since superpostion can occur for that observable, then it makes sense that it should be possible for OTHER observables". This is simply not true since this is very system-dependent. Just becaue an electron can be in superpostion of spin, doesn't mean its charge must also be in such a state. So far, the arguments that superpostion of energy/wavelength/freq/ for an individual photons have been built via that line.

Concerning the electron's charge, there are different answers possible, but the simplest is that EVERY electron has one and the same charge. So this is a Hilbert space with only one dimension, which makes superposition trivial.
The superposition principle states that ALL POSSIBLE STATES can occur in a superposition. Some people have introduced a few superselection rules, such as boson/fermion interdiction, or charge interdiction. But it is a result of decoherence that you do not need those superselection rules: they are dynamically generated. So the superposition principle is universal.

The example I showed you was a femtosecond laser. Of course it are gazilion photons that come out, but I wanted to argue that they can ONLY have a time relationship if they are all in the same, pure state which is a superposition of momentum states.
Unfortunately, we don't have femtosecond photomultipliers. So it is only a preparation, and not a measurement. Nevertheless, I hope you believe that out of a femtosecond laser, come pulses which have a very short duration of which the photons are synchronized in time (or bunched in space, for a given value of time). Otherwise you've been had by the salesman of the laser!
So in the same way as out of a polarizer come only 45 degree polarised photons, even if there are a lot of them (in identical states), I am trying to convince you that out of such a laser come photons which are (at a given t) bunched in position, all of them, in identical "position" states. And the only way to have that is by having them in a superposition of momentum states.
But it is true that I don't have a SINGLE PHOTON source. It is a MANY IDENTICAL PHOTON source. And in that respect it is different from an incandescent bulb, which sends out a statistical mixture of different photons, in different states.
But any momentum filter, or spectral analysis, will screw up your nice difference between the pulsed source and the light bulb, like your HV filter screwed up your nice 45 degree polarized light as compared to unpolarized light from a light bulb. The only measurement proving this would be a femtosecond photomultiplier. But I don't know of any.

cheers,
patrick.
 
Last edited:
  • #84
chemistryknight said:
I read this question in a book. but i think a color of a photon is an expression of it's energy . the white light is consist of 7 colours ( 7 frequencies ) . and the photon can exist in one frequency only ( energy = f * h ) .
if we have white light source extremely dim to produce one photon how could we see it ?
can anyone help me
i think ,
to solve this problem we must not cocentrate on photons produced from light source , or eye ( sensor ) respectors. But the answer is near if we take into account the way that the white light source produce this photons.
I read all what you wrote , and this guide me to this idea .
The answer of my question - i think - is " white one photon cannot exist ". The light source excited and in the delay to ground state it emit 3 photons at the same time , the 3 photon product of 3 (e.g.) eleectrons exictation.
and the rest of my idea is now clear 2 you

if i on the right way?
 
  • #85
The original question asks if the intensity of white light is reduced to individual photon detections, what will they represent? Will there be individual photons that represent a range of energy (ie frequencies) as we understand white light to be? That is a good question. If so then we would be quite justified in calling that a "white photon" regardless of the make up of our eye, or issues of physiological perception etc. Just remember that photons are the quanta of the field, and E=hv was discovered by Einstein himself. Remember the photoelectric effect, he increased the voltage and just got more photons, not more energy per photon.
In the case of white light, just follow Newton. The separation of frequencies is dead easy, just use diffraction. Glass prisms will do. Ultimately you will find that extra prisms don't make a lot of difference, you can pretty well decide that you have a spectral distribution of frequency, which according to quantum theory is simply a spectral distribution of energies. And you will not be able to split your light any more than that.
That should convince you you don't have white photons. You might be tempted to think that the glass prisms "caused" the "photons to split". But then you would be inventing new physics about diffraction that you can't justify.
 
  • #86
Notice that I said nothing about atoms and energy transitions. There is nothing to stop the energy distribution in the light beam from being as a continuum, it doesn't just have to be generated or for that matter absorbed, from the process of atomic transitions. So what does that do to the possibility of having white photons? Sorry but it is the same deal. You see, instead of thinking about particles having energy, it is more useful in the case of the light field to think of energy having particles. Again this was realized when Einstein sponsored Bose to publish what became known as the Bose-Einstein statistics. You see photons are not conserved like electrons. They invent themselves all the time, according to the energy requirements. So you see your continuum beam would happily go through the glass prism and produce a population of photons, with a range of energies, about which we could not say much apart from the overall probabilities. If you still not happy about the glass, then imagine your beam is so weak that you are only detecting one photon per day. It would be detected at one position after refraction. Thats it.
 
Last edited:
  • #87
kaonyx said:
The original question asks if the intensity of white light is reduced to individual photon detections, what will they represent? Will there be individual photons that represent a range of energy (ie frequencies) as we understand white light to be?
[...]
If you still not happy about the glass, then imagine your beam is so weak that you are only detecting one photon per day. It would be detected at one position after refraction.

It is a common misconception that reducing the intensity of some arbitrary beam can give you single photons. This is not the case. Single detection events do not mean that you have single photons present. If you reduce the intensity of some coherent beam, the photon number distribution will stay Poissonian and even if you have on detection per day on average, you will still get some two-photon detection events as predicted by Poissonian statistics. The only way to show that you have true single photon states lies in measuring the variance of the photon number distribution or equivalently second-order correlations.
 
  • #88
Wow! Not sure how one digs out something from way back in 2005 to necropost.

Zz.
 
  • #89
Oh, ouch. I did not even notice that only the last two posts before mine are new and the others are ancient. Sorry for taking part in resurrecting the dead.
 
  • #90
It is not a popular misconception, it is a fact. The Poisson distribution simply means that photons arrive at purely random times. They are detected singly because they are just that, single photons. The randomness is in the arrival times between successive photons. The physical meaning of this randomness is that the electric field always contains some uncertainty in its value. You can modify this distribution of arrival times by quantum mechanical technology, such as non-linear optical systems that produce phase effects such as quadrature squeezing. What that achieves is that either the times between photon arrivals are a bit closer together than you expect classically, or conversely they can be a bit less closer together - commonly known as bunching or anti-bunching and is quantum mechanical, not classical. Photons tend to bunch slightly anyway, and electrons tend to anti-bunch, and you can demonstrate both effects with either particle. Photon number is simply a conjugate property of the phase, these things are how we describe the wave as a quantum mechanical wave function, so none of this changes the fact that these are photons, pure and simple, quanta of energy with a characteristic frequency, or if you prefer - colour.
So yes you can reduce the intensity down to a single photon (a gedankenexperiment) and you will detect a red photon and then a blue photon etc coming out of your prism with plenty of random time lag between them to convince yourself that there are no white photons. Case closed.
 
  • #91
kaonyx said:
It is not a popular misconception, it is a fact. The Poisson distribution simply means that photons arrive at purely random times. They are detected singly because they are just that, single photons.

This is pure nonsense. If you claim to have single photons you need to demonstrate antibunching. The Poisson distribution means that detection events are distributed statistically independent of each other. However, whether these belong to just a single field originating from a single emitter (single photon) or from many fields originating from different emitters possibly including contributions from more than one field (coherent or thermal light for example) cannot be distinguished just by knowing that "single clicks" were the origin of the detection events. Do you have any peer-reviewed publication that shares your opinion that even in Poisson distributed light there are always single photons? Kimble et al. say otherwise (Phys. Rev. Lett. 39, 691–695 (1977)). Also, showing antibunching is THE tool to identify single photon sources today, see e.g. Science 290, 2282-2285 (2000) by Peter Michler et. al.

kaonyx said:
The randomness is in the arrival times between successive photons. The physical meaning of this randomness is that the electric field always contains some uncertainty in its value. You can modify this distribution of arrival times by quantum mechanical technology, such as non-linear optical systems that produce phase effects such as quadrature squeezing. What that achieves is that either the times between photon arrivals are a bit closer together than you expect classically, or conversely they can be a bit less closer together - commonly known as bunching or anti-bunching and is quantum mechanical, not classical.

Sure, but you can have each of these for any amount of intensity. Only antibunching corresponds to single photons.

kaonyx said:
Photons tend to bunch slightly anyway

Thermal light tends to bunch, coherent light does not. The emission from single photon sources of course also does not bunch.

kaonyx said:
Photon number is simply a conjugate property of the phase, these things are how we describe the wave as a quantum mechanical wave function, so none of this changes the fact that these are photons, pure and simple, quanta of energy with a characteristic frequency, or if you prefer - colour.

That basically means that you have the opinion that Glauber's theory of coherence is not necessary and nonsense.

kaonyx said:
So yes you can reduce the intensity down to a single photon (a gedankenexperiment) and you will detect a red photon and then a blue photon etc coming out of your prism with plenty of random time lag between them to convince yourself that there are no white photons. Case closed.

You can reduce it to a single photon detection per time unit ON AVERAGE. Still, most of the work of Mandel and part of the Nobel prize winning work of Glauber was devoted to showing that you need a hierarchy of correlation functions to describe a light field most precisely and that you need at least second order correlations to identify single photons.
 
  • #92
In between bunching and antibunching is neither. So if we start with bunched statistics, or neither, you are suggesting that reducing the intensity must alter the shape of the distribution?
 
  • #93
It's a basic fact of Fourier decomposition that a finite (in time) entity does not have a single frequency, it has a spectrum.

If the line width of a single quantum is sharp, it has a definite energy. And it must therefore persist for an indefinite time.

The math is not forgiving on this topic. A photon that has N cycles in it's wavetrain can only have a definite energy (zero linewidth) as N approaches infinity.
 
  • #94
It was amusing to me to see this pop up as a necro-thread, and also to see how many posts and how much sophisticated argumentation had gone into it. I'm the person who wrote the discussion question: http://www.lightandmatter.com/html_books/lm/ch34/ch34.html [Broken] The book is targeted at biology majors who haven't had calculus. Although I included the discussion question in my book, I think I have never actually used it with any of my classes over the years. My intention was simply that the answer would be "yes, of course, because photons are waves, and waves can superpose, so you can superpose a bunch of different wavelengths."
 
Last edited by a moderator:
  • #95
But surely photons are not waves, they are photons., particles, they can collide with other particles e.g. xrays with electrons and impart momentum to the electron. The properties of the photons themselves are subject to the uncertainty principle so you have to be a bit guarded when imagining you can have two of then localised in a radiation field, so that you can create a superposition in the way that you might be able to do by bringing two relatively massive bodies like electrons together into a chemical bond. Photons can all share the same state anyway so is that really a valid way to create a new superposition state?

As far as the Fourier analysis of the wave goes, are we not talking about two different kinds of wave here? The electromagnetic wave (Maxwell) is not exactly the same thing as the quantum wave (Schrodinger) is it? I mean the electric field can be uncertain but these quantum waves have a kind of platonic form? I think you can use the maxwell wave to compute the quantum wave, (that's handy!) but one is a field equation and the other is a probability wave. The Fourier breakdown of quantum wave packet gives probability amplitudes, not energies?
 
  • #96
kaonyx said:
In between bunching and antibunching is neither. So if we start with bunched statistics, or neither, you are suggesting that reducing the intensity must alter the shape of the distribution?

No, of course not. It is exactly my argument that you do not get single photons by reducing the intensity of a coherent/thermal beam because you do not change the statistics, only the mean photon number.

kaonyx said:
But surely photons are not waves, they are photons., particles, they can collide with other particles e.g. xrays with electrons and impart momentum to the electron. The properties of the photons themselves are subject to the uncertainty principle so you have to be a bit guarded when imagining you can have two of then localised in a radiation field, so that you can create a superposition in the way that you might be able to do by bringing two relatively massive bodies like electrons together into a chemical bond. Photons can all share the same state anyway so is that really a valid way to create a new superposition state?

Well, at least all photons inside a coherence volume are indistinguishable and you have to treat them that way which means that they behave very differently from independent single photons in that case. You will also only see a thermal photon number distribution if you consider indistinguishable photons in a coherence volume. Outside of it, they are usually never distributed thermally. QED and quantum optics are still field theories after all.
 
<h2>1. Can a white photon exist?</h2><p>The concept of a "white photon" is not well-defined in physics. Photons are particles of electromagnetic radiation that have a range of energies and frequencies, but the color white is a perception based on the combination of different wavelengths of light. So, while a photon can have a wide range of colors, it cannot be considered "white" in the traditional sense.</p><h2>2. How is the color of a photon determined?</h2><p>The color of a photon is determined by its frequency, which is related to its energy. Higher frequency photons have shorter wavelengths and are perceived as having a bluer color, while lower frequency photons have longer wavelengths and are perceived as having a redder color. The entire spectrum of colors, including white, can be created by combining different frequencies of photons.</p><h2>3. Can white light be made up of only one type of photon?</h2><p>No, white light is made up of a mixture of photons with different frequencies. In fact, a single photon only has one specific frequency and therefore one specific color. White light is typically a combination of many different colors of photons, such as those found in sunlight or produced by a light bulb.</p><h2>4. Is it possible to create a white photon?</h2><p>As mentioned before, the concept of a "white photon" is not well-defined in physics. However, it is possible to create a beam of light that appears white to our eyes by combining photons of different colors. This can be achieved through a process called color mixing, where different colored lights are combined to create the perception of white light.</p><h2>5. Are there any real-life applications for white photons?</h2><p>Since white photons are not a well-defined concept, there are no specific applications for them. However, the ability to create white light using a combination of different colored photons has many practical applications, such as in lighting, photography, and display technologies. Additionally, understanding the properties of photons and their interactions is crucial in fields such as quantum mechanics and particle physics.</p>

1. Can a white photon exist?

The concept of a "white photon" is not well-defined in physics. Photons are particles of electromagnetic radiation that have a range of energies and frequencies, but the color white is a perception based on the combination of different wavelengths of light. So, while a photon can have a wide range of colors, it cannot be considered "white" in the traditional sense.

2. How is the color of a photon determined?

The color of a photon is determined by its frequency, which is related to its energy. Higher frequency photons have shorter wavelengths and are perceived as having a bluer color, while lower frequency photons have longer wavelengths and are perceived as having a redder color. The entire spectrum of colors, including white, can be created by combining different frequencies of photons.

3. Can white light be made up of only one type of photon?

No, white light is made up of a mixture of photons with different frequencies. In fact, a single photon only has one specific frequency and therefore one specific color. White light is typically a combination of many different colors of photons, such as those found in sunlight or produced by a light bulb.

4. Is it possible to create a white photon?

As mentioned before, the concept of a "white photon" is not well-defined in physics. However, it is possible to create a beam of light that appears white to our eyes by combining photons of different colors. This can be achieved through a process called color mixing, where different colored lights are combined to create the perception of white light.

5. Are there any real-life applications for white photons?

Since white photons are not a well-defined concept, there are no specific applications for them. However, the ability to create white light using a combination of different colored photons has many practical applications, such as in lighting, photography, and display technologies. Additionally, understanding the properties of photons and their interactions is crucial in fields such as quantum mechanics and particle physics.

Similar threads

Replies
78
Views
3K
Replies
16
Views
1K
Replies
8
Views
854
  • Quantum Physics
2
Replies
38
Views
3K
Replies
1
Views
262
  • Quantum Physics
2
Replies
64
Views
3K
  • Quantum Physics
3
Replies
81
Views
4K
  • Quantum Physics
Replies
12
Views
668
  • Quantum Physics
Replies
10
Views
2K
  • Quantum Physics
Replies
1
Views
834
Back
Top