Can the photoelectric effect be explained without photons?

Question

Lamb 1969 states,

A misconception which most physicists acquire in their formative years is that the photoelectric effect requires the quantization of the electromagnetic field for its explanation. [...] In fact we shall see that the photoelectric effect may be completely explained without invoking the concept of "light quanta."

The paper gives a description in which an atom is ionized by light, with the atom being treated quantum-mechanically but the light being treated as a classical wave.

Is it true that all the standard treatments in textbooks are getting this wrong?

Lamb and Scully "The photoelectric effect without photons," in "Polarization, Matière et Rayonnement," Volume in Honour of A. Kastler (Presses Universitaires de France, Paris, 1969) -- can be found online by googling

This post imported from StackExchange Physics at 2015-03-05 15:11 (UTC), posted by SE-user Ben Crowell

Comments

see also the discussion in physicsforums.com/threads/…

This post imported from StackExchange Physics at 2015-03-05 17:36 (UTC), posted by SE-user Arnold Neumaier

Answer 1

Yes,the photoelectric effect can be explained without photons!

One can read it in

L. Mandel and E. Wolf, Optical Coherence and Quantum Optics, Cambridge University Press, 1995,

a standard reference for quantum optics. Sections 9.1-9.5 show that the electron field responds to a classical external electromagnetic radiation field by emitting electrons according to Poisson-law probabilities, very much like that interpreted by Einstein in terms of light particles. Thus the quantum detector produces discrete Poisson-distributed clicks, although the source is completely continuous, and there are no photons at all in the quantum mechanical model. The state space of this quantum system consists of multi-electron states only. So here the multi-electron system (followed by a macroscopic decoherence process that leads to the multiple dot localization of the emitted electron field) is responsible for the creation of the dot pattern. This proves that the clicks cannot be taken to be a proof of the existence of photons.

An interesting collection of articles explaining different current views is in

The Nature of Light: What Is a Photon?
Optics and Photonics News, October 2003
http://www.osa-opn.org/Content/ViewFile.aspx?Id=3185

Further discussion is given in the entry ''The photoelectric effect'' of my theoretical physics FAQ at http://arnold-neumaier.at/physfaq/physics-faq.html . See also my slides at http://arnold-neumaier.at/ms/lightslides.pdf http://arnold-neumaier.at/ms/optslides.pdf

QED and photons are of course needed to explain special quantum effects of light revealed in modern experiments, but not for the photoeffect.

This post imported from StackExchange Physics at 2015-03-05 17:37 (UTC), posted by SE-user Arnold Neumaier

Comments

+1 because this was the kind of thing I was expecting as an answer to this question, rather than the self-answer at the top. I can't believe this is answer is sitting so low down.

This post imported from StackExchange Physics at 2015-03-05 17:37 (UTC), posted by SE-user New_new_newbie

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Well, I would just like to add that this discussion relates to the overall discussion on how does a quantization of a field relate to a notion of a particle. Phonons are a quantization of the acoustic disturbance of a crystal, they will propagate quite like quantum particles, electrons will scatter on them, they will come in energy quanta, yet the current picture would be that they are not fundamentally particles. That is, in the continuum limit (wavelengths well above the crystal grid length), the mathematical theory makes no distinction between the fundamental nature of a photon and a phonon.

The truth is that it seems that 1) measurable outputs of any microscopic experiments are particles, and 2) if a field is not part of a measurable output, our mathematical apparatus does not make a distinction between a quantum-interacting field and a field-particle. Hence, by Occam's razor, a quantum-interacting field and a field-particle cannot really be considered a different entity!

In other words, a field which only interacts in resonance with quantized systems and a field quantized in particle-packets is not really different when considered from the point of view of empirically constructed notions. So, in some sense these discussions seem to me to be an issue of nonempirical ontology and semantics.

Answer 2

The Lamb-Scully paper is a good example of how even a Nobel Prize winner can occasionally write a bad paper.

The historical context is important. Einstein hypothesized the photon in 1905, but his paper was ahead of its time and was not widely accepted. For decades afterward, even once the quantum-mechanical nature of the atom was assumed by all physicists, the quantum-mechanical nature of light was considered suspect. Bohr was influential in pushing a theory in which atoms were quantized, but the light they absorbed and emitted was classical. Lamb began his career during this era.

If you read the Lamb-Scully paper, the first thing you notice is that they explicitly state that photons are absolutely necessary in order to explain phenomena such as blackbody radiation, Compton scattering, spontaneous emission, and the Lamb shift. Any internet kooks who are trying to quote Lamb and Scully as authorities against quantization of light are way off base.

As in Bohr's old-fashioned dead-end approach, they then treat the atom as a quantum-mechanical system and the electromagnetic field as a classical one. They are able to reproduce the Einstein relation $E=hf-W$, where $E$ is the maximum energy of the electron once it leaves the cathode, $h$ is the quantum-mechanical Planck's constant, $f$ is the frequency of the light, and $W$ is the energy required for the electron to escape through the surface of the cathode. This is not particularly surprising or impressive in a bastardized quantum/classical calculation like this one; essentially it just says that the light wave has to have the energy taken out of it at a resonant frequency of the atom, that frequency has to match its own frequency.

They also show that the transition rate is nonzero even when the light is first turned on, saying that their result "certainly does not imply the 'time delay' which some people used to expect for the photoelectrons produced by a classical e.m. field." This result is not as impressive as they make it sound, since the classical prediction is what one expects for a classical light wave impinging on classical atoms.

In fact, the transition rate they derive shows the real problem with their calculation. Their calculation treats every atom as independent of all the other atoms. Therefore if a classical flash of light with energy $W$ illuminates the cathode, it may ionize more than one atom, violating conservation of energy. This unphysical result shows the opposite of what they claim; it shows that their mixed quantum-classical Frankenstein fails to provide a physically acceptable explanation of the photoelectric effect. What they really need is a quantum-mechanical entanglement between the different parts of the photon's wave packet, so that if the photon is observed at atom A, it is guaranteed not to be observed at atom B. Without this quantum-mechanical "spooky action at a distance," their theory violates conservation of energy.

This issue was recognized very early on in the development of the "old" quantum theory, and it led to the Bohr-Kramers-Slater (BKS) theory, in which energy and momentum were conjectured to be conserved only on a statistical basis. Experiments as early as Bothe 1925 falsified the BKS theory by showing that when x-rays were emitted in a spherical wave into two hemispherical detectors, the two detectors were completely anticorrelated.

A modern discussion of these issues is given by Greenstein 2005. In section 2.1, they first present a summary of the Lamb-Scully argument, and then discuss the experimental verification of the existence of the anticorrelations required in order to maintain conservation of energy (Grangier 1986). The fact that this anticorrelation was not successfully observed with visible light until 1986 was due to technical limitations on the ability to produce sources of light that were eigenstates of photon number. However, the equivalent anticorrelation result with x-rays had already been demonstrated by Bothe in 1925.

One could therefore argue that the observations of the photoelectric effect were not enough to establish the existence of photons without the further verification of anticorrelations some years years later. This would be misleading, however. From the point of view of physicists reading Einstein's 1905 paper, before the quantum-mechanical nature of the atom had been established, a hybrid model such as Lamb's or the BKS theory was unavailable, and therefore the photoelectric effect really did require quantization of light. One could argue that, in the historical context of the period from 1913 (the Bohr model) to 1925 (Bothe), there was a viable BKS theory that avoided quantization of the electromagnetic field, but this is extremely misleading when modern authors such as Lamb fail to admit that nonconservation of energy was an ingredient.

Similar difficulties arise if one attempts to construct a consistent theory in which the gravitational field simply isn't quantized, unlike the other fundamental forces (Carlip 2008).

Bothe and Geiger, "Experimentelles zur Theorie von Bohr, Kramers und Slater," Die Naturwissenschaften 13 (1925) 440. The experiment is described in Bothe's 1954 Nobel Prize lecture.

Carlip, "Is quantum gravity necessary?," http://arxiv.org/abs/0803.3456

Grangier, Roger, and Aspect, "Experimental evidence for a photon anticorrelation effect on a beamsplitter," Europhys. Lett. 1 (1986) 173 -- can be found online by googling

Greenstein and Zajonc, "The quantum challenge: modern research on the foundations of quantum mechanics," Jones and Bartlett, 2005.

This post imported from StackExchange Physics at 2015-03-05 15:13 (UTC), posted by SE-user Ben Crowell

Comments

note that a semi-classical treatment of Compton scattering (which Schrödinger derived in 1927) does get parts of the physics right - but not all of it (as with the photoelectric effect, you need QED for that); also note that a semi-classical approach that attributes clicks of a detector in optical experiments to the quantum nature of the detector (instead of the field) can be closer to reality than the naive picture of photon particles hitting the detector - a QED photon is inherently delocalized and shouldn't be confused with localized wave packets (which we sometimes call photons as well)

This post imported from StackExchange Physics at 2015-03-05 15:14 (UTC), posted by SE-user Christoph

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From what I remember, it's certainly the case that, in the context of the photoelectric effect, textbooks generally give the impression that it's just the discreteness of the photodetections which provide evidence for the quantum nature of light - it would be more illuminating (sorry) if they mentioned that discreteness occurs also in semiclassical theories, but that it leads to difficulties with energy conservation.

This post imported from StackExchange Physics at 2015-03-05 15:14 (UTC), posted by SE-user twistor59

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@twistor59: it would be more illuminating (sorry) if they mentioned that discreteness occurs also in semiclassical theories, but that it leads to difficulties with energy conservation. Such an approach would beg the question of why semiclassical theories are even worth considering. The reasons they were considered are IMO obscure and historical and not of much interest to modern students. There are infinitely many wrong theories we could set up for our students and then shoot down. How much of that to do is a matter of taste.

This post imported from StackExchange Physics at 2015-03-05 15:14 (UTC), posted by SE-user Ben Crowell

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@BenCrowell I disagree with your last comment. To follow you, we should never teach Newton's law, because it's of no much interest for modern students ? Your answer is definitely great by the way, even if I would erase the first sentence. I also subtly modify the interpretation usually when discussing with friends. I prefer to argue that neither the atom nor the light field is quantised (in a provocative way), but it's rather the exchange energy between the two sub-systems which is quantised.

This post imported from StackExchange Physics at 2015-03-05 15:15 (UTC), posted by SE-user FraSchelle

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@BenCrowell And I would certainly also moderate the motivation of Lamb and Scully. I believe they first of all tried to make a tribute to Kastler. Usually, you dedicate really original articles for this, that you will also present in front of an incredibly specialised and competent audience. That's clearly what they did: changing the mind of everyone attending to this conference, or at least installing some doubts in their mind.

This post imported from StackExchange Physics at 2015-03-05 15:15 (UTC), posted by SE-user FraSchelle

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Re: your second to last paragraph which begins "One could therefore...". It doesn't make sense to say that "an experiment established the existence of X at the time it was run, but later X ceased to be established by the experiment because a theorist came up with an alternative explanation". Instead, one would say "people thought X was established by the experiment, but then a theorist showed that this was in error."

This post imported from StackExchange Physics at 2015-03-05 15:15 (UTC), posted by SE-user Jess Riedel

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-1: It is easy to dismiss a 50 ears old paper. But try to do the same with the 2003 collection of articles cited in my answer!

This post imported from StackExchange Physics at 2015-03-05 15:15 (UTC), posted by SE-user Arnold Neumaier

Answer 3

Yes, the textbooks are getting it very wrong.

The common narrative on these things is best summarized by the "three nails in the coffin" approach: the dead body being the wave theory of light, and the three nails being the blackbody spectrum, the photo-electric effect, and the Compton effect. Whatever difficulties the wave theory may or may not have with modern anti-correlation experiments, they are completely wrong in the arguments they present for rejecting the wave theory on the basis of the "three nails".

The reason textbooks, and physicists in those days, accepted those wrong arguments is that until 1926 there was no viable theory which allowed people to do wave-on-wave calculations. Once Schroedinger discovered the wave equations, clear explanations were available for all three phenomena. I will describe them briefly here.

First, the photo-electric effect. Even today modern textbooks make much of the frequency threshold, as though that were inexplicable by classical waves. The Schroedinger theory made it immediately clear that states of different enery levels are coupled only when excited by frequencies corresponding to the difference in those levels. Yet the textbooks continue to profess bafflement at the frequency effect.

The other glaring error of the textbooks is in using the physical cross-section of a single atom to calculate the absorption cross-section. Even Scully is guilty of this in a paper as recent as 2002 (if I remember the year). The physical cross-section is completely wrong even in antenna theory; if it were true, a crystal radio could never collect enough energy to drive even the tiniest of earphones. I explain this in my blogpost on the crystal radio. (And I don't think anyone wants to argue that you need photons to explain the crystal radio.)

Second, the Compton Effect. When I figured out a semi-classical explanation of the Compton Effect, I thought I would win the Nobel Prize. So I was disappointed to find that Schroedinger had published exactly the same explanation in 1927. You take the light and the electron in a center-of-mass system, and you consider the system at the midpoint of the interaction...when the electron is in a superposition of states, half moving to the left, and half moving to the right. You can see right away that this superposition sets up layers of charge equally spaced at a distance of 1/2-lambda, creating a perfect diffraction grating for total reflection.

Of course Compton couldn't have come up with this explanation because he didn't know about electron waves. His "proof" debunking the wave theory of light treated the electon as a tiny charged ping-pong ball.

Finally, the black-body spectrum is an interesting case. Oddly enought, it is known that Planck's Law must prevail even if electromagnetism didn't exist, as exemplified by low-temperature specific heat of solids. The deviation from the law of Dulong and Petit was (I think) recognized by Einstein in a 1905 paper. But it is hard to argue that it is caused by "photons". Surely we must believe that the suppression of the high-frequency modes is here just a mechanical consequence of Schroedinger's Equation.

And if that is so, then there is no need to invoke "photons" to explanation the extension of Planck's Law to the electromagnetic spectrum, because a careful classical argument shows that the energy per mode at any given frequency of the classical e-m field must be equal to the energy per mode of the mechanical oscillators at that same frequency. I show how this calculation works in a series of articles culminating here.

For good measure, I also explicitly show in a later series of blog posts that the Copenhagen "quantum leap" between eigenstates gives the same radiation field as the Schroedinger continuous transition model with the atoms radiating semi-classically.

Thanks to Helder Velez for flagging some of my articles. Yes, I am the kook identified as such by Ben Crowell, so feel free to ignore my post.

This post imported from StackExchange Physics at 2015-03-05 15:15 (UTC), posted by SE-user Marty Green

Comments

Nobody disputes that semi-classical theories such as Bohr-Kramers-Slater (or rehashes of it by Lamb or you) can explain some aspects of these phenomena. A viable theory needs to explain all of the observations. Whatever difficulties the wave theory may or may not have with modern anti-correlation experiments [...] "Modern" is misleading. BKS was proposed in 1924, then disproved in 1924-1925 in a series of experiments by Bothe and Geiger, one of which observed exactly the anticorrelations predicted by the photon theory.

This post imported from StackExchange Physics at 2015-03-05 15:15 (UTC), posted by SE-user Ben Crowell

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The question is specifically about the photoelectric effect, so the material about Compton scattering and black-body radiation is off topic. However, a semi-classical picture of Compton scattering can't explain (1) a change in wavelength in the limit of low-intensity incident radiation, or (2) the results of the 1924 Bothe-Geiger electron-x-ray coincidence experiment.

This post imported from StackExchange Physics at 2015-03-05 15:16 (UTC), posted by SE-user Ben Crowell

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Ben, the textbooks dispute precisely those aspects of these phenomena which can be explained by a good semi-classical approach. And I'm not talking about BKS...you obviously haven't had time in the 16 minutes since I posted to read the articles where I show how it's done.

This post imported from StackExchange Physics at 2015-03-05 15:16 (UTC), posted by SE-user Marty Green

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Ben, you're the one that introduced Compton and Black Body into the discussion, not me.So you shouldn't criticize me for going "off-topic". There's nothing in the original post about anti-correlation either. The question was about whether the "textbooks" have it wrong, meaning I would think the common undergrad textbooks with their "three nails" narrative. I think I answered the question.

This post imported from StackExchange Physics at 2015-03-05 15:16 (UTC), posted by SE-user Marty Green

Answer 4

I disagree with OP in that I don't consider energy conservation as a fatal flaw.

If one lets $t\to\infty$ in the perturbative calcualtion, one gets a nice delta function $\delta(\epsilon_f-\epsilon_i-\hbar\omega)$ but in such case the external energy supply is infinite and no meaningful energy conservation argument can be formulated, so I guess OP must be talking about the finite-time result, so let's focus on this.

Following OP's argument, actually we don't even need two atoms to see energy is not "conserved", one atom is enough. The result of harmonic perturbation gives the probability of transition from ground state $|g\rangle$ to the kth exited state $|k\rangle$ as(quoting Lamb&Scully equation (13))

$4\left|\frac{\langle k|\hat x|g\rangle E_0}{\hbar}\right|^2\frac{\sin^2\{(\epsilon_k\hbar^{-1}-\nu)t/2\}}{(\epsilon_k\hbar^{-1}-\nu)^2}$

, where $E_0$ is the external EM wave E-field strength. Normally the matrix element $\langle k|\hat x|g\rangle $ can be non-zero up to $|k\rangle$ with arbitrarily high energy. For classical light, we can make $E_0$ arbitrarily close to 0, this means in a finite $t$ the energy supply can be arbitrarily small, yet the probability is non-zero for the transition to a $|k\rangle$ with very high energy(i.e. $\epsilon_k-\epsilon_g>$external energy supply). If after a measurement the atom indeed ends up at $|k\rangle$, then energy conservation is violated.

However what is the reason of this violation? It is because our energy measurement for external EM wave is classical while the energy measurement for the atom is quantum mechanical. In other words, we are comparing initial energy with some eigenvalue $\epsilon_k$ of the quantum Hamiltonian. In a fully quantum mechanical(i.e. not semi-classical) system, this is exactly what we should not do; what we should compare are the energy expectation values, that is \, something like initial $\langle i|H|i\rangle$ and final $\langle f|H|f\rangle$, but never just some eigenvalues(unless both are eigenstates). So if we do the same in the semi-classical treatment of photo-electric effet, we see energy conservation is satisfied qualitatively, because from equation $(13)$ we see the energy expectation value will be proportional to $|E_0|^2$. I believe the same argument applies to OP's two-atom experiment.

I must say OP's argument is justified for a semi-classical system, because it's certainly operationally possible. But my point is that this is a generic problem of all semi-classical systems(in fact there has been similar argument showing that if light is treated classically then uncertainty principle for electron can be violated. See Sakurai"Advanced quantum mechanics" page 34~35). So I think it's good enough that Lamb and Schully could reproduce $E=\hbar\omega-\phi$ and the no-delay emission of electrons. If one wants to use energy conservation as an objection, one might as well just say quantum-classical coupling is impossible, there's no need to assign any special significance to the photo-electric effect.

EDIT: I'd like to move my last comment to the main text for the sake of completeness. The energy conservation difficulty is only conceptual not experimental, because the very original photoelectric effect could only measure energy expectation values, and from my above analysis we see energy expectation values are conserved. Even on a conceptual level, there's still a way out, that is, take energy conservation to be true only on a statistical level(which of course needs experimental test, and indeed there were as Ben mentioned), and this was exactly what Bohr proposed, due to exactly the same reason. In a word, I believe Lamb & Scully did explain all experimental aspects of photoelectric effect.

This post imported from StackExchange Physics at 2015-03-05 15:16 (UTC), posted by SE-user Jia Yiyang

Comments

Nice answer, +1. I think we only differ in emphasis. If one wants to use energy conservation as an objection, one might as well just say quantum-classical coupling is impossible, there's no need to assign any special significance to the photo-electric effect. I agree. The photoelectric effect is just one example that demonstrates the general impossibility of quantum-classical coupling. But historically it was one of the first and most important such examples in the development of quantum mechanics, and pedagogically it's a nicer intro than the Compton effect or black body radiation.

This post imported from StackExchange Physics at 2015-03-05 15:16 (UTC), posted by SE-user Ben Crowell

Answer 5

All the above explanations describe measurable effects at endpoints of energetic interaction, they do not demonstrate photons as anything other than a concept of pure convenience that derives historically from the dreaded billiard ball analogy. The "so-called" propagation of the interaction energy is observable only at the endpoints and the effect is associated with c (the so called speed of light), so at c time and space dilation make the endpoints essentially the same event. It's important to divest yourself of the anthropomorphic boundaries of observability. The "effect" you are measuring is not only loaded with your bias to a notion of time and distance but also to causality. The end point effects do not require there to be a photon. The very notion of one is an anachronism.

This post imported from StackExchange Physics at 2015-03-05 17:37 (UTC), posted by SE-user Peter Russell

Answer 6

No! Infact the existence of photons is cruciall to the photoelectric effect. To understand why this is so, think of the billard ball collision, Photons collide with electron in a metal with a specfic work function,the electron intern absorb the energy of the photon; instead of reflecting the light completly, according to classical wave theory of light.

This post imported from StackExchange Physics at 2015-03-05 17:37 (UTC), posted by SE-user user34793

Comments

You've just said that photons are a sufficient condition in order to explain the photoelectric effect. But you haven't explained if they are a neccesary condition.

This post imported from StackExchange Physics at 2015-03-05 17:37 (UTC), posted by SE-user jinawee

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That isn't entirely true... Please read the last sentence of my comment...

This post imported from StackExchange Physics at 2015-03-05 17:37 (UTC), posted by SE-user user34793