Talk:Quantum mechanics/Archive 10

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I'm a newbie to wikipedia so hopefully I haven't stepped on any toes. Apologies in advance if I have.

I've recently edited the Quantum Mechanics page and changed the first few lines to try to dispel the (often commonly held) belief that quantum mechanics is about nature at the "small scale". More accurately quantum mechanics describes nature at all scales but is *absolutely necessary* for describing nature at small scales.

I think that the opening line of the Quantum Mechanics article: "Quantum mechanics (QM; also known as quantum physics, quantum theory, the wave mechanical model, or matrix mechanics), including quantum field theory, is a fundamental theory in physics which describes nature at the small – atomic and subatomic – scales." is misleading in the sense that quantum mechanics is not only about the small scale. It applies at all scales. It explains the existence of metals, semiconductors, insulators, and the structure of the periodic table (which underpins all of chemistry, and is the basis of quantum chemistry). To a large degree solid state physics (which describes macroscopic objects) would not be understandable without quantum mechanics.

The misconception about quantum mechanics only applying at the small scale is somewhat clarified later in the "Quantum mechanics" article where there are several statements about quantum mechanics applying at all scales, such as: "Most theories in classical physics can be derived from quantum mechanics as an approximation valid at large (macroscopic) scale." and the entire section on "Relation to classical physics".

Nonetheless, I believe that the article could be improved by avoiding the "small scale" trap right off the bat. I would suggest changing the article to read

"Quantum mechanics (QM; also known as quantum physics, quantum theory, the wave mechanical model, or matrix mechanics), including quantum field theory, is a fundamental theory in physics describing the properties nature[2].

Classical physics, the description of physics that existed before the formulation of the theory of relativity and of quantum mechanics, describes many aspects of nature at ordinary (macroscopic) scale. Quantum mechanics explains the aspects of nature at ordinary (macroscopic) scales but extends this description to the small – atomic and subatomic – scales. "

Papaneeds (talk) 00:56, 5 March 2020 (UTC)papaneeds

The passages you have changed cite two sources - one by Nobel prize winner Richard Feynman and one 2014 published paper by Gregg Jaeger. It would be a good idea to verify that your new versions still summarize what these cited sources say. Dirac66 (talk) 03:36, 5 March 2020 (UTC)

No. QM is a description of the very small. That a few macro manifestations (such as superconductivity) can be observed at macro scales, does not alter this premise. By way of example, Relativistic theories are associated with the very fast, even though they apply in theory to everyday life (and GPS which isn't really that fast). That QM can manifest at larger scales is already mentioned, as you said. If QM explains the existence of "metals, semiconductors, insulators etc" then it does so by describing them at a SMALL scale. However, the requirement is that you quote a 3rd Party Reliable Source for your proposed change of emphasis. <Phecda109>. — Preceding unsigned comment added by 2407:7000:A244:E161:ADAA:4BDA:3348:BD42 (talk) 19:30, 16 May 2020 (UTC)

I agree, QM is the physics of small scales, numerous textbooks [1] p.8, [2] p.1, [3] p.3, [4], p.4 support this. I think the word small should be in the introduction. The current wording: "It describes physical properties of nature on an atomic scale." may be a little misleading, giving the impression that it applies only to atomic scale and not smaller scales. --Chetvorno^TALK 21:38, 3 August 2020 (UTC)

I'm late to the party, but I want to post this in case anyone else is wondering about the same. There is a very important nuance here that most people miss: Yes, Quantum mechanics is the foundation for all of modern physics and (most of) classical mechanics can be derived from it. However, and this is very important, it is completely impractical for describing the nature of objects on the human-scale. You cannot keep track of an Avogadro number of degrees of freedom. Statistical mechanics is useful in this region. Relativistic mechanics, as far as we can tell, is always valid but it is totally unnecessary at low speeds (v << c). Just as general relativity is not necessary to describe gravity on earth or the moon. Attempting to do so is, generally, folly. There are scales in physics, we have to make compromises (approximations) to make the best models we can with the information and resources at our disposal (hence statistical physics). In order to better appeal to nontechnical readers, I believe it is best that quantum mechanics and quantum physics are talked about as the physics of the small at the beginning, as that is what many of them are here to read about. Mentions, deeper in the article, to the applications of QM to these other fields seems appropriate. Footlessmouse (talk) 11:18, 16 August 2020 (UTC)

I agree with @Chetvorno:, the "atomic scale" sounds like other scales are excluded. But to say "small scale" would be immensely imprecise - small compared to what? QM is actually more about subatomic scales: we rarely use it to describe motion of atoms and molecules as a whole (He scattering), and more to describe their constituents. Shall we say the scale is the "particle scale"? How granular do we need to see Nature to start describing it by QM - that defines the scale. The effects can spread to mezzo and macroscopic scales, but the description starts with... particles. Your thoughts? Ponor (talk) 07:22, 18 August 2020 (UTC)

I think "atoms and subatomic particles" is sufficiently specific. QM certainly is required to describe interactions of atoms and molecules as a whole, in chemistry. --Chetvorno^TALK 16:36, 18 August 2020 (UTC)

Chemistry is mainly QM of the outer electrons, so we're still subatomic. We don't take neutral atoms and write wavefunctions for each without considering their electrons and stuff. But OK, we do have helium scattering, superfluid helium etc. where things are not too grainy. I didn't want to be disrespectful, but I reverted your "and smaller" edit. Subatomic particles already include everything from photons to nuclei. Ponor (talk) 16:57, 18 August 2020 (UTC)

No problem with your edit, "and smaller" was probably a bad idea. I do think "atoms" should be in there, as "of the order of subatomic particles" implies that quantum mechanics is not needed at atomic scale. Atoms are entirely quantum mechanical objects, wouldn't exist without QM. The wording is also supported by most sources: [5] p.8, [6], p.4 --Chetvorno^TALK 17:41, 18 August 2020 (UTC)

Atoms and subatomic particles are there to explain the scale, so we're describing anything between 0.1x and 10x of their size - I think we're fine! This is how I understand the scales: it's the smallest objects you need to use to describe your system. Atoms are quantum objects (when they absorb or emit light, bond to each other, etc.) because of their electrons. And are quantum objects because of their nuclei (when you probe nuclei). And nucleons (when you probe nucleons). And are quantum objects as a whole when they scatter off of surfaces (wavelike interference!), or condense in a superfluid, but in this case we don't care about their electrons that much (because energies involved do not excite them), we take them as quantum, 0.1 nm small billiard balls. Just saying... Cheers! Ponor (talk) 19:40, 18 August 2020 (UTC)

I agree with this. I think another major point is: there is no clear cut distinction. When trying to model a system, you start with the easiest model first (classical approximations) and, when it fails to account for experimental data, you upgrade to more complicated models. I think the new statement, after edits by @Chetvorno and @Ponor, are pretty perfect for the lead. It is clear and precise enough without going into too much detail. Footlessmouse (talk) 20:05, 18 August 2020 (UTC)

I agree that QM extends beyond small scale (I will try an edit). CaveWriting (talk) 21:37, 11 September 2020 (UTC)

I think a few of the effects of quantum mechanics, like superconductivity, superfluidity, and entanglement, are detectable at large scales, but they are still the results of interactions between particles at the atomic or subatomic scale. I think the addition to the introduction is misleading. --Chetvorno^TALK 21:55, 11 September 2020 (UTC)

The added statement, the new second sentence of the article, is very jarring. The lead is trying to convey the fact that quantum mechanics is only used in regimes where classical mechanics is insufficient. IMO, that is all it needs to do. Mentioning macroscopic quantum effects in the introduction to the quantum mechanics article is not particularly helpful to readers who don't understand quantum mechanics, I agree with @Chetvorno that it is somewhat misleading. Footlessmouse (talk) 22:12, 11 September 2020 (UTC)

We are entangled at large scales (nonlocality) because our constituent particles were at the same state during the Big Bang, which was the entangling event. At that level, we all share the same wave function (state). The laws of QM evolved our separate states going forward from that event.^[1]

References

--Ancheta Wis   (talk | contribs) 23:07, 11 September 2020 (UTC)

This is a fact that a god-like observer outside the universe would appreciate. Notes on how these concepts extend outside the realm of the particle-scale interactions should be placed lower in the article in a manner that is not confusing to readers unfamiliar with quantum mechanics. Quantum mechanics deals with systems in which we can keep track of all the degrees of freedom, maybe Quantum statistical mechanics is more appropriate for such notes. Footlessmouse (talk) 23:55, 11 September 2020 (UTC)

Hi all, if the articles are to be split, does anyone mind if we copy over the philosophy stuffs to the other page? I do not think I am the only one who has said this page should be about quantum mechanics and no physics major is taught about this stuff in their physics classes, so it does not seem particularly relevant here, except maybe a very brief mention and links to other articles. History can also be trimmed with some of the content being used to fill out the History of quantum mechanics article. The example sections should be cut down drastically. Schrodinger equation is mentioned six times outside examples and is not defined. Matrix mechanics is not mentioned outside a single reference. Path integral formulation is mentioned as a side note. Pauli matrices are not discussed!!! These facts are absurd! I would say this article is much more about the history, philosophy, and applications of QM than it is about QM, which otherwise does not have a coherent article on this encyclopedia. Thank you for completing the split @Benica11:, that is step one.Footlessmouse (talk) 08:05, 7 October 2020 (UTC)

I'm not sure this split was adequately discussed, and I oppose it. If you want a split of the application parts then Quantum technology is a much better target. Quantum mechanics IS the physics of quantum behaviour. So I would say this split is inappropriate and is going to make a mess of our coverage of quantum physics as it is basically a content fork. Polyamorph (talk) 08:14, 7 October 2020 (UTC)

@Polyamorph: the discussion was open for weeks with consensus, why didn't you object before? Also, did you read my comment? This page currently has no substantive quantum mechanics material in it. We should work on expanding it with relevant material that will actually tell the reader what quantum mechanics is. I know we physicists like to be lazy with words when talking with other physicists, but this is an encyclopedia and words matter. Philosophy and history and applications are NOT quantum mechanics. They are simply philosophy, history, and applications of a subject. Quantum mechanics is not discussed in a meaningful way. (How can you possibly pretend to have learned anything about quantum mechanics at all if you were not even shown Pauli matrices???)Footlessmouse (talk) 09:18, 7 October 2020 (UTC)

Um, just because it was open for a few weeks does not mean everyone got a chance to see it - I didn't object because I didn't see it. This is such a fundamental subject that I don't feel the comments from a handful of users on this page can possibly represent the true consensus. Just because the page is bad is no reason to split and potentially create deleterious content forks. It's instead a case of working to improve the existing content. Regarding history and philosophy, this is an encyclopedia and full coverage of the subject is indeed appropriate. If such sections get out of hand they can then be split into independent articles and referenced using {{main}}. Polyamorph (talk) 09:23, 7 October 2020 (UTC)

@Polyamorph:, they already have main articles and what is on this page is supposed to summarize, but goes into too much detail. I must admit, I do not care about "quantum physics" and only wanted the split to get rid of all the junk on the page that is supposed to be about "quantum mechanics". They can all be summarized, but currently the whole page is summaries of those things with absolutely no meaningful exposition on quantum mechanics. It's not a matter of improving the content, it's a matter of writing a large amount of new content to replace what's here. I would support a move of the page "Quantum physics" to a "Applications of quantum mechanics" if that appeases others.Footlessmouse (talk) 09:42, 7 October 2020 (UTC)

Why support something that you don't think is the optimal solution. We can't create pages just to put "all the junk" somewhere else, that's just kicking the can down the road. Polyamorph (talk) 09:46, 7 October 2020 (UTC)

But yes, I would say Applications of quantum mechanics would be a better target. IMO QM is the Physics. Applications are technology. Polyamorph (talk) 09:49, 7 October 2020 (UTC)

@Polyamorph: I apologize, that is fair. I also really wanted to close that discussion so we could move on to discussing the content. I will support your move to Applications, it is very appropriate. To be honest, the literature has always ambiguous when it comes to quantum mechanics versus quantum physics. I have always held, though, that quantum mechanics is simply the adaptation of Hamiltonian mechanics to situations where it was previously invalid, requiring an inherently probabilistic approach that is nonsensical from a classical perspective.Footlessmouse (talk) 10:05, 7 October 2020 (UTC)

No problem @Footlessmouse:, thanks for understanding! cheers! :) Polyamorph (talk) 10:38, 7 October 2020 (UTC)

As a professional physicist, I want to add that we use quantum mechanics and quantum physics as synonyms. Neither is very well-defined, but generally include all quantum theories. When we want to be precise, we specify that we are working with non-relativistic quantum mechanics, or QFT, or quantum information, or QCD, etc. Tercer (talk) 10:13, 7 October 2020 (UTC)

Side note, even those terms are dependent upon your specialty, part of the reason so many terms are ambiguous. As a CM physicist, I can state as a matter of fact that we never refer to it as non-relativistic quantum mechanics, as (in most specialties) our systems of concern are non-relativistic. There should be a Wikipedia article about terms in science with a disclaimer that says most terms scientists use are context dependent.Footlessmouse (talk) 10:25, 7 October 2020 (UTC)

I concur with Tercer — I've pretty much always heard those terms used effectively synonymously. In my own writing, I employ both, just so the phrasing doesn't get too repetitious. XOR'easter (talk) 18:45, 8 October 2020 (UTC)

When @Laura sf proposed the split, it seemed like she had a clear idea of what to do. We pinged her a few times since then, and there was no response. So I think this split came a bit too soon. Quantum physics (QP) is not just applications of quantum mechanic (QM), it's almost everything that happened in physics since ~193* (after They were done with developing QM). Would I say that quantum statistical physics is part of QM? No, I would not. Is it a branch of QP - yes it is. Nuclear physics, particle physics, atomic physics, condensed matter physics? They're all branches/fields of QP, not QM. In my opinion, QP article should be about fields that have QM in their foundation. It should say that they emerged from our need to describe Nature at the most fundamental level (el. particles and energy quanta), and give a one-sentence introduction to each. Condensed matter deals with interactions emerging in many-body systems of valence electrons and atomic cores. Nuclear physics deals with QM description of protons and neutrons bound by nuclear interaction. And so on. Then there can be sections with more specific examples/applications from each of these high-level fields, that will more or less point to separate articles. When it comes to QM article, I think it's better to keep it short: it can mention perturbation methods, but does not need to elaborate on them. It can say in which cases we need them, but not how we use them. It can mention Pauli matrices (what they're used for), different formulations of QM (elaborate on the most prevalent one), but should not try to say everything about them. All low-level details should stay one click away. Your thoughts? Ponor (talk) 19:59, 7 October 2020 (UTC)

@Ponor:, we do already have articles on Modern physics and Classical physics and I think your definition may be a duplicate of the content that belongs in modern physics. It would otherwise require turning modern physics into a disambiguation for quantum physics and relativity. I get both sides of the argument and am a little torn. Woe us, if only some authoritative literature could help us out!Footlessmouse (talk) 21:06, 7 October 2020 (UTC)

@Footlessmouse: I know... that's why I hoped Laura sf would do it. Does is hurt to leave the two articles like this for some time (no changes is QM until QP is written) and see how things evolve? For in the third sentence of Modern physics we have: "Notable branches of modern physics include quantum physics (sic!), special relativity, and general relativity." Also, Modern physics in an unsearchable term; you may only stumble upon it. Quantum physics, to me, is much more real. It might be interesting to see what pageview counts QM and QP will have. Ponor (talk) 21:37, 7 October 2020 (UTC)

@Ponor and Polyamorph: What if we create a new page titled "Quantum (adjective)"? It is unambiguous and could be used to disambiguate popular jargon and list all fields that utilize QM, just like the QP article would. As regards to Modern physics article, it is highly underdeveloped and it should have said quantum mechanics rather than quantum physics, mentioning it in one breath with the relativities. If it said, "Notable branches of modern physics include astrophysics, cosmology, and quantum physics, I would agree, but in this case I think the wording of the page is wrong.Footlessmouse (talk) 21:51, 7 October 2020 (UTC)

I feel Quantum (adjective) would be insufficiently specific; articles about adjectives are more dictionary entries. We need to title articles with enough specificity so general readers can find what they are looking for. A list of all fields of study in QM would not take up much space and could be incorporated in this article (or whatever toplevel QM article is decided on). Another possibility is List of quantum physics articles or List of fields of study in quantum mechanics. --Chetvorno^TALK 22:38, 7 October 2020 (UTC)

I meant that it would discuss how the adjective modifies the rest of the term. Explaining the difference between classical and quantum physics is far beyond the scope of any dictionary. My main argument this whole time was that all that stuff doesn't belong here, I think this page desperately needs be rewritten to actually discuss QM, like, you know, for starters, Pauli matrices, wave mechanics, matrix mechanics, path integral (I'll even take sum over histories). The current article is a long expose of quantum caveats with some examples, applications, history, and philosophy mixed in. There is no mechanics.Footlessmouse (talk) 22:59, 7 October 2020 (UTC)

@Footlessmouse: I'm not sure about this, before creating any new articles I think it would be useful to generate a list of articles wikipedia already has on quantum theory, see which ones overlap, and then see if we can formulate a merge/split/cleanup/expand plan to ensure full and proper coverage of quantum theory/physics/technology. Hope that makes sense. Polyamorph (talk) 07:57, 8 October 2020 (UTC)

@Footlessmouse: I kind of agree with you that the mathematical basis of QM like the Schrodinger equation and Pauli matrices is given sort shrift in this article (I understand why, there's a lot of other stuff to cover). An option I've thought about is rewriting Introduction to quantum mechanics to make it a technical introduction. The current Introduction to quantum mechanics is more about the history of QM. We could move the historical content of that article into History of quantum mechanics (where it really belongs) and replace it with a proper mathematical introduction to QM touching on the stuff you mentioned, maybe along the lines of Feynman. --Chetvorno^TALK 23:04, 7 October 2020 (UTC)

@Chetvorno: This is a decent idea. I would be okay with it if the hatnote mentioned that "This is an overview of topics relating to quantum mechanics, for a mathematical introduction to the subject see..."Footlessmouse (talk) 23:14, 7 October 2020 (UTC)

Following the recent split discussed above of content from here to Quantum physics, it has been suggested that since much of the content moved to Quantum physics deals with various applications then Applications of quantum mechanics might have been a better target. I'm therefore re-opening the split discussion with three options. 1) Keep the two articles Quantum Mechanics and Quantum physics split as they are. 2) Move Quantum physics to Applications of quantum mechanics and redirect Quantum physics to Quantum mechanics. 3) Merge content currently at Quantum physics to Quantum technology and redirect Quantum physics to here. 4) Undo the split to Quantum physics entirely and focus on cleanup of this article. 5) Other (please elaborate).

!Votes

• Option 2 or 3 In my opinion Quantum mechanics is the physics of quantum behaviour, so it makes sense for Quantum physics to redirect here. The short section on Applications of quantum mechanics can remain with the {{main}} target updated to Applications of quantum mechanics. However, Applications of Quantum Mechanics and Quantum technology are arguably synonymous. So I would also support a merge of the applications content to Quantum technology. Polyamorph (talk) 12:09, 7 October 2020 (UTC) EDIT: Following XOR'easter's comment I agree there are applications of quantum mechanics that are not technology so I'm striking option 3.Polyamorph (talk) 09:14, 9 October 2020 (UTC)

• Option 2 or 3 While, in my opinion, quantum mechanics is mechanics, an inherently mathematical modelling of physical systems, I agree with the other points.Footlessmouse (talk) 16:12, 7 October 2020 (UTC)

• Option 2 or 3. "Quantum physics" is something you find in popular science descriptions, but what they mean is almost always quantum mechanics. A separate article for that doesn't make sense. --mfb (talk) 19:37, 7 October 2020 (UTC)

• Option 1 Quantum mechanics is the foundation. Its development was over in 1930s. That's where most textbooks on QM stop. What emerged were different fields that used QM (AND statistical physics AND field theory AND many, many approximations) to describe Nature at the most fundamental level (el. particles and en. quanta). Those fields are part of quantum physics. So no, QM and QP are not the same. No, QP is not a popular science thing (Nature:Quantum physics). More thoughts in the previous section... Ponor (talk) 20:14, 7 October 2020 (UTC)

• Option 2 or 4 In 20+ years of working with physicists, reading physics papers and books, and doing physics myself, I've never heard a clear-cut distinction made between "quantum physics" and "quantum mechanics". To illustrate, MIT calls its undergraduate courses "Quantum Physics" (8.04 through 8.06), while Caltech labels its undergrad classes on the same material "Quantum Mechanics" (Ph 125 abc). It's possible that some people do have a distinction in mind, but we should not presume that a reader would pick up on it, or that everyone who makes a distinction does so in the same way. All this talk of moving, merging, splitting and renaming is making my head spin, and I don't think it will ultimately lead to any clarity. Nor do I quite follow the rationales that have been advanced so far. No, the term "quantum physics" is not restricted to pop science; "quantum technology" is not the same thing as "applications of quantum mechanics" (the latter might include, for example, applying quantum physics to calculate the spectral lines of a quasar, something with no technological application — it is a much more general turn of phrase). XOR'easter (talk) 19:10, 8 October 2020 (UTC)

• Option 2 makes the most sense to me. Nerd271 (talk) 18:03, 9 October 2020 (UTC)

• Option 2 for reasons above. I think this article should be what it already is: a nonmathematical introduction to QM and WP:summary style umbrella article on all Wikipedia's quantum content. This article has a readable prose size of only 52kb so there is room to add stuff. I also share Footlessmouse's concern that Wikipedia has no proper mathematical introduction to QM, giving Schrodinger's equation, Born probability eq, postulates of QM, uncertainty principle, unitary matrices, etc. Without the mathematical introduction, the Examples section of this article is pretty incomprehensible. I suggest either adding a brief mathematical introductory section to this article, or creating a new article covering this. One option I suggested above is to rewrite Introduction to quantum mechanics as a nathematical introduction, moving the existing historical content to History of quantum mechanics. --Chetvorno^TALK 00:10, 10 October 2020 (UTC)

Are people still interested in this reorganization? It looks like the proposal that gained the most support was to Move Quantum physics to Applications of quantum mechanics and redirect Quantum physics to Quantum mechanics. XOR'easter (talk) 01:58, 12 December 2020 (UTC)

Quantum physics has a life of its own, and since 17 August 2020 a growing number of readers (inc. from 100 to 600 a day). An article called "Applications of quantum mechanics" will be nearly unsearchable; if "Quantum physics" bothers anyone, its contents should just be put back into "Quantum mechanics". "Quantum physics" was and still is in Modern physics, as one of its branches. Please also remember that polls should not be used for article development, per WP:Vote. I'd like to see a broader consensus before proceeding; though I don't see how having Quantum physics hurts. Your quantum physicist (quantum mechanic?) for 22+ years, Ponor (talk) 07:13, 12 December 2020 (UTC)

There was an extensive discussion already, and consensus has emerged. You were the only one arguing for keeping things as it is. I think having "Quantum Physics" does hurt, for two reasons: first most people think of quantum physics and quantum mechanics as synonyms, the readers won't be able to find the correct article to get the content they want even if we here manage to come up with a sensible distinction between them. The second reason is that the actual content of the Quantum physics article is indeed just applications of quantum mechanics, it's much more helpful to have a title that matches the content. Tercer (talk) 13:11, 12 December 2020 (UTC)

I would do the deed myself but Applications of quantum mechanics already exists as a redirect, so we need an admin to delete that before we can do the move. Tercer (talk) 13:27, 12 December 2020 (UTC)

I've filed at Wikipedia:Requested moves to move Quantum physics over the redirect. XOR'easter (talk) 17:34, 12 December 2020 (UTC)

XOR'easter, I've completed the move to Applications of quantum mechanics. ─ The Aafī ^(talk) 18:13, 12 December 2020 (UTC)

@Tercer:I don't see any discussion, I only see a few people voting. A few months ago we had consensus to start Quantum physics, the "splitting" (spin-off) proposal was announced at Project Physics list and people were invited to comment. Unfortunately, the original proposer vanished and the split was rushed. Then the Applications section was removed from Quantum mechanics (with that consensus in mind, I assume), and now we're creating another article with what should really still be in Quantum mechanics as its very important part (most readers will be interested in what QM is, and how it can be taxed). How about we follow some procedure: revert everything to the status quo ante, start discussion on whether to create yet another quantum article called "Applications of quantum mechanics", invite members of WikiProject Physics to comment, etc. Btw: who is "most people" for you? If you follow my google scholar link in the previous posting, you'll see thousands of researchers listing "Quantum Physics" as their research field. It would be nice to actually discuss all this for a change. Ponor (talk) 18:16, 12 December 2020 (UTC)

We ... did have a discussion? (Just because people summarized their opinions with a little bold text here and there doesn't mean they were voting — that's why the section heading was "!Votes", after all, with the bang denoting negation.) We discussed, almost everyone found option 2 to be acceptable, the discussion petered out, and now we've implemented the change that consensus had settled on. This is Wikipedia procedure.

As for the Google Scholar bit, sure, people list "quantum physics" as their research field. Others list "quantum mechanics". That's not evidence we should prefer one terminology over the other. XOR'easter (talk) 18:29, 12 December 2020 (UTC)

Procedure was followed. This is how a discussion and consensus looks like. Your current proposal to revert everything and start discussion anew was actually one of the options there, which was not supported even by yourself. About Google Scholar: I'm not sure what it is that you're to prove. That many people use the term "quantum physics"? Sure, nobody is disputing this. What I said is only that "quantum physics" and "quantum mechanics" are effectively synonyms. Tercer (talk) 20:01, 12 December 2020 (UTC)

Agree with Tercer, I am strongly against reopening the proposal. We had an adequate discussion above, and 6 editors voted to redirect Quantum physics. The only reason it wasn't implemented immediately was to give people plenty of time to comment. They've had plenty. Time to close this discussion. --Chetvorno^TALK 21:36, 12 December 2020 (UTC)

Hi

While I have been editing Wikipedia for many years in different topics, many of them in physics, I have refrained so far from editing this particular page, as I am mainly interested in either correcting errors or adding new material. However, I must admit that I find the structure of this article problematic. While the article is very impressive in the amount of material and in elaborating the history and the mathematical tools used in quantum mechanics, I feel it is too focused on the history and less on the subject matter at hand, and the subject matter itself is mainly presented by mentioning the mathematical tools used, with very little explanation of the reasons behind using these tools, which I feel have a much better understanding today compared to when they were first invented.

I believe it would be very difficult for a student to understand what is going on from reading this article. Having finished a PhD in string theory many year ago, I personally have no problem with this, but having taught many new students in the past, I think they would find it very difficult to gain good understanding of quantum mechanics from reading this article alone.

Therefore I suggest to add an "overview" part before the history part, which will cover the fundamental issues and main ideas and results in a compact way. I have in fact started working on this.

I would love to hear your opinions/suggestions/(dis)agreement on the matter.Dan Gluck (talk) 14:56, 24 November 2020 (UTC)

I would also like to see progress made on this page, an overview section sounds reasonable to me. We have also discussed creating a technical introduction aside from this article that would be more along the lines of what a calculus-knowledgeable physics student would read if they were interested in learning more, which I think is a good idea as well. Footlessmouse (talk) 23:02, 24 November 2020 (UTC)

Agree with both the above. I'm not knowledgeable enough to help write such a section myself, but I would support it if you guys want to do it. --Chetvorno^TALK 22:01, 12 December 2020 (UTC)

There's an overview section now (added by Dan Gluck on November 30). XOR'easter (talk) 02:35, 13 December 2020 (UTC)

I'm rather unhappy with the resulting "Overview" section. It is rather long, give too much detail, and mixes precise mathematical statements with arguments that do not actually follow. For example, it claims that Every basis vector may have different values of these, so position and momentum must be defined as linear operators in quantum mechanics, having different results on different basis vectors. and that This relation is identical to the one found in Fourier transform, so that a description of an object according to its momentum is the Fourier transform of its description according to its position.. This needs to be fixed. But instead of chopping it down now, I'll start adding actual mathematics to the "mathematical formulation" section, which only has mathematics in form of words (I find this bizarre, mathematics in mathematical symbols is much easier to understand). Then we can remove the inappropriate material from "Overview". Tercer (talk) 20:09, 14 December 2020 (UTC)

Actually, I think that after the overview we should have a section about the 5 postulates. There is no justification to put the math in a separate section. Dan Gluck (talk) 21:38, 14 December 2020 (UTC)

I think it is a good idea to start with an overview of what the important concepts are, before diving down to the mathematics. I put the sections closer together, but I think keeping them separate is better. As for using formal postulates, the problem is that with Wikipedia's usual growth-by-accretion such a list tends to become garbage. See here, for example. To compound that, there's no well-defined or consensually accepted list of what the postulates are, on the contrary, one can do the postulates in several different ways that work just fine.

Either way, postulates or flowing text, we need a mathematical description of the theory. I wrote a bit about Hilbert spaces, quantum states, observables, and measurements. It's not good, but it's much better than the dumpster fire that was there before. Notably missing is still anything about composite systems and the uncertainty principle. Tercer (talk) 15:56, 15 December 2020 (UTC)

I like the idea of starting with a big-picture view of the concepts before diving down into the Hilbert spaces and Hermitian operators and tensor products. Some of what's in the "Overview" section now feels like it already wants to start diving. I moved the "uncertainty principle" material into the next section, where it seems to fit better. XOR'easter (talk) 18:15, 15 December 2020 (UTC)

I added a little bit about composite systems and entanglement. XOR'easter (talk) 03:05, 16 December 2020 (UTC)

Should the article introduce Dirac notation? XOR'easter (talk) 00:27, 22 December 2020 (UTC)

I was wondering about this as well. I decided not to do it, because I assume that the target audience of this article is kids that are taking their first quantum mechanics course, and very often this course is done without the use of Dirac notation. There's also the question of where it would help. There are only a couple of equations when we talk about measurements that would be clearer in Dirac notation, the rest would stay the same. So I don't think the benefit is worth the effort in introducing it. Tercer (talk) 09:48, 22 December 2020 (UTC)

That's fair. The question occurred to me when I thought about writing something about Mach–Zehnder interferometers and realized that I was instinctively going for ${\displaystyle |0\rangle }$ and ${\displaystyle |1\rangle }$. XOR'easter (talk) 19:44, 22 December 2020 (UTC)

Hehe I need to make a conscious effort to use regular vectors instead of kets. I started gathering some material about the Mach-Zehnder in my sandbox, feel free to use it. Tercer (talk) 21:11, 22 December 2020 (UTC)

OK, I mixed that with some text I had on hand and added the result to the "Examples" section. It probably needs some reworking and/or expansion. XOR'easter (talk) 21:53, 22 December 2020 (UTC)

I reworked it a lot. Maybe I put too many details, but I find this example fascinating because the math is so easy, even a schoolkid can follow it, so I think it is worth being completely explicit. Tercer (talk) 13:59, 23 December 2020 (UTC)

I've fixed all the problems I've noted with this article, and am going to nominate it as WP:GOOD. Before, though, I thought I could ask here if there's some problem that escaped my attention but is obvious to somebody else's eyes. Tercer (talk) 22:06, 30 December 2020 (UTC)

I have no objection to GA nomination. I've fixed all that I've noticed; further progress will probably require a fresh set of eyes that aren't so accustomed to the text that they see what's supposed to be there. XOR'easter (talk) 02:50, 6 January 2021 (UTC)

Thanks for the feedback, I nominated it. Tercer (talk) 14:18, 6 January 2021 (UTC)

This review is transcluded from Talk:Quantum mechanics/GA1. The edit link for this section can be used to add comments to the review.

Reviewer: Ján Kepler (talk · contribs) 06:53, 5 March 2021 (UTC)

Hi, thanks for nominating the article. As a quantum mechanics "fan", I'll try to review it. I plan to read the article this weekend, but at first glance, it looks good. --Ján Kepler (talk) 06:53, 5 March 2021 (UTC)

Thanks for volunteering to review the article. I'll address your comments. Tercer (talk) 09:09, 13 March 2021 (UTC)

GA review (see here for what the criteria are, and here for what they are not)

1. It is reasonably well written.

   a (prose, spelling, and grammar): b (MoS for lead, layout, word choice, fiction, and lists):

2. It is factually accurate and verifiable.

   a (reference section): b (citations to reliable sources): c (OR): d (copyvio and plagiarism):

3. It is broad in its coverage.

   a (major aspects): b (focused):

4. It follows the neutral point of view policy.

   Fair representation without bias:

5. It is stable.

   No edit wars, etc.:

   This version is stable for several months already, so yes.

6. It is illustrated by images and other media, where possible and appropriate.

   a (images are tagged and non-free content have fair use rationales): b (appropriate use with suitable captions):

   User:Tercer I would replace the very first image for some more instructive one, but maybe there aren't any? --Ján Kepler (talk) 08:07, 14 March 2021 (UTC)

   I like that image; it represents one of the earliest successes of quantum theory, and is something that makes perfect sense to draw in real space. In general illustrating quantum mechanics is rather difficult. If you have a specific idea I'd be happy to hear. Tercer (talk) 09:07, 14 March 2021 (UTC)

7. Overall:

   Pass/Fail:

Comments

Overview Let's dive into it. I already made some edits to the article, but feel free to revert them. The comments below are just idea how to improve the article.

• It is typically applied to microscopic systems: molecules, atoms and sub-atomic particles. – The word typically looks confusing to me in this sentence. Or does it mean that some people apply it to macroscopic systems?

  Yes, it does mean that it is also applied to macroscopic systems. I rewrote it to make this point more explicit. Tercer (talk) 09:49, 13 March 2021 (UTC)

• Applying the Born rule to these amplitudes gives a probability density function for the position that the electron will be found to have when an experiment is performed to measure it. – maybe add that it DOESN'T say WHERE the electron is (it could be confusing like this for some people?)

  Indeed, we should emphasize that the properties are probabilistic. Done. Tercer (talk) 09:49, 13 March 2021 (UTC)

• their properties become so intertwined that a description of the whole solely in terms of the individual parts is no longer possible. – maybe this is described too complicatedly? For example the definition here I find much more straightforward (that the quantum state of each particle of the pair or group cannot be described independently of the state of the others, including when the particles are separated by a large distance.).

  The definition in quantum entanglement is misleading. One can attribute an independent quantum state to the individual parts, a reduced density matrix. The problem is that these independent states are not enough to describe the whole entangled state, one necessarily loses information. This is explained more precisely in the section Quantum_mechanics#Composite_systems_and_entanglement, I wanted to leave the Overview section as nontechnical as possible. Tercer (talk) 09:49, 13 March 2021 (UTC)

Mathematical formulation

• In the mathematically rigorous formulation of quantum mechanics developed by Paul Dirac,[15] David Hilbert,[16] John von Neumann,[17] and Hermann Weyl,[18]] – was it really only these four? — Preceding unsigned comment added by Ján Kepler (talk • contribs) 08:07, 13 March 2021 (UTC)

  No, quantum mechanics was developed by dozens of people. It culminated with the work of von Neumann, from them on it stayed essentially unchanged. But it's silly to try to do a proper attribution in this section, its goal is to present the mathematical formulation, attribution belongs in the History section. I removed this sentence. Tercer (talk) 09:57, 13 March 2021 (UTC)

• I like how is this section written: I think it's the most straightforward way it can be written, but I would advise you to contact someone from WikiProject Physics to review this part. Overall, as this is a very important article, I will ask for a second opinion after I complete the review.

  I am the person from WikiProject Physics that would review that. I have a PhD in physics and my area of research is quantum mechanics. Of course, I don't object to a second opinion, it is a very important article and it is perfectly possible that I missed something. Tercer (talk) 09:07, 14 March 2021 (UTC)

• The uncertainty principle states that {\displaystyle \sigma _{X}\sigma _{P}\geq {\frac {\hbar }{2}}.}{\displaystyle \sigma _{X}\sigma _{P}\geq {\frac {\hbar }{2}}.} – maybe write somewhere what does the "h" mean as it wasn't mentioned anywhere in the article before? --Ján Kepler (talk) 08:03, 14 March 2021 (UTC)

  Good catch, I introduced the missing definition. Tercer (talk) 09:19, 14 March 2021 (UTC)

Examples

• and the "upper" path {\displaystyle \psi _{u}={\begin{pmatrix}0\\1\end{pmatrix}}}{\displaystyle \psi _{u}={\begin{pmatrix}0\\1\end{pmatrix}}}, that is, {\displaystyle \psi =\alpha \psi _{l}+\beta \psi _{u}}{\displaystyle \psi =\alpha \psi _{l}+\beta \psi _{u}} for complex {\displaystyle \alpha ,\beta }\alpha ,\beta such that {\displaystyle |\alpha |^{2}+|\beta |^{2}=1}{\displaystyle |\alpha |^{2}+|\beta |^{2}=1}. – the last statement (abs alpha squared... + beta ... = 1) was also never mentioned in the article before, so maybe put a link to somewhere in parenthesis?

  That's just the normalisation requirement, I added an explanation. Tercer (talk) 13:13, 14 March 2021 (UTC)

• will then end up in the state {\displaystyle BPB\psi _{l}=ie^{i\Delta \Phi /2}{\begin{pmatrix}-\sin(\Delta \Phi /2)\\\cos(\Delta \Phi /2)\end{pmatrix}},}{\displaystyle BPB\psi _{l}=ie^{i\Delta \Phi /2}{\begin{pmatrix}-\sin(\Delta \Phi /2)\\\cos(\Delta \Phi /2)\end{pmatrix}},} what does BPB mean?

  The multiplication of the B, P, and B matrices. I clarified the text. Tercer (talk) 13:13, 14 March 2021 (UTC)

Applications

• Solid-state physics and materials science are dependent upon quantum mechanics. – I know this is very obvious, but maybe still add a reference?

  Sure, I added a reference. Tercer (talk) 13:24, 14 March 2021 (UTC)

• In many aspects modern technology operates at a scale where quantum effects are significant. Important applications of quantum theory include quantum chemistry, quantum optics, quantum computing, superconducting magnets, light-emitting diodes, the optical amplifier and the laser, the transistor and semiconductors such as the microprocessor, medical and research imaging such as magnetic resonance imaging and electron microscopy.' – perhaps add quantum teleportation? --Ján Kepler (talk) 10:58, 14 March 2021 (UTC)

  I don't think quantum teleportation is an application; it is a fundamental effect, but until now it wasn't used for anything. Tercer (talk) 13:13, 14 March 2021 (UTC)

Relation

• large quantum numbers. – how much is large?

  It's not well-defined, this is just a heuristic, not a mathematical theorem. It is described in the source. Tercer (talk) 15:38, 17 March 2021 (UTC)

• Quantum electrodynamics is, along with general relativity, one of the most accurate physical theories ever devised – maybe add even more references?

  Why? Anything wrong with them? Tercer (talk) 15:38, 17 March 2021 (UTC)

Philosophy

• This is not accomplished by introducing a "new axiom" to quantum mechanics, but by removing the axiom of the collapse of the wave packet. All possible states of the measured system and the measuring apparatus, together with the observer, are present in a real physical quantum superposition. While the multiverse is deterministic, we perceive non-deterministic behavior governed by probabilities, because we don't observe the multiverse as a whole, but only one parallel universe at a time. Exactly how this is supposed to work has been the subject of much debate. Why we should assign probabilities at all to outcomes that are certain to occur in some worlds, and why should the probabilities be given by the Born rule? – shouldn't this be in quote marks?

  Why? It is not a quotation. Tercer (talk) 15:38, 17 March 2021 (UTC)

  Well then it's OR, no? Wikipedia articles shouldn't ask questions. — Preceding unsigned comment added by Ján Kepler (talk • contribs) 16:36, 17 March 2021 (UTC)

  It's phrased as questions, but they're questions that have been asked in the literature, as the cited sources indicate. Nothing original on our part. Maybe the phrasing could be tweaked to clarify this? (It seems clear enough to me at present, but somebody might have a good idea for an improvement.) XOR'easter (talk) 17:50, 17 March 2021 (UTC)

  I would definitely edit it, because it doesn't make sense to have question marks in Wikipedia articles when it's not a quotation. --Ján Kepler (talk) 11:29, 18 March 2021 (UTC)

  I don't see the problem with having a question mark per se. We are reporting on questions that have been asked in the literature. It paraphrases this quotation by Wallace [7]: It is useful to identify two aspects of the problem. The first might be called the incoherence problem: how, when every outcome actually occurs, can it even make sense to view the result of a measurement as uncertain? Even were this solved, there would then remain a quantitative problem: why is that uncertainty quantified according to the quantum probability rule (i. e. , the Born rule), and not (for instance) some other assignment of probabilities to branches?. Tercer (talk) 12:00, 18 March 2021 (UTC)

  I don't know how to do it, but in this version, is unacceptable for me. Who is we? And should Wikipedia articles really have words like should? Also having one source on This is not accomplished by introducing a "new axiom" isn't very good in my opinion. I get what that the paragraph is just a summary of some quantum mechanics interpretation, but I think it's now done in a bad way. Why not just say something like "MWI thinks X and Y, because of Z"? After fixing this, the article would definitely pass GAC.--Ján Kepler (talk) 07:24, 20 March 2021 (UTC)

  Ok, I see your point, the paragraph is written in an argumentative style, which is not very encyclopedic. I've rewritten it to make it more straightforward and remove excessive detail. Tercer (talk) 10:36, 20 March 2021 (UTC)

History

• No mentions about de Broglie?

  He should be mentioned, I added a couple of sentences. We have to be careful not to put too much detail, in order to keep with summary style. Tercer (talk) 15:38, 17 March 2021 (UTC)

GA

I think the article now passes the GAC, do you agree XOR'easter so I can close this? --Ján Kepler (talk) 16:32, 22 March 2021 (UTC)

I was actively involved in editing the article prior to its nomination, so nothing I say here should count as a reviewer's opinion. But I do think the article is in pretty good shape, and the GA review process did improve it, for which I am thankful. XOR'easter (talk) 16:38, 22 March 2021 (UTC)

OK, the article passed GA criteria. Thanks to both of you (and others who've written the article)! --Ján Kepler (talk) 19:25, 22 March 2021 (UTC)

I'm glad to hear that! Thanks again for volunteering. Tercer (talk) 21:35, 22 March 2021 (UTC)

This edit request to Quantum mechanics has been answered. Set the |answered= or |ans= parameter to no to reactivate your request.

hi, im tim. i like orange juice. Daddyjjjshh (talk) 18:56, 10 March 2021 (UTC)

 Not done Not a request to make an edit to the article. –LaundryPizza03 (dc̄) 18:59, 10 March 2021 (UTC)

@Ancheta Wis: I appreciate the vouch of confidence, but I merely didn't get around to editing the "see also" section. As for the change in question, note that MOS:NOTSEEALSO is not an absolute rule. Since bra-ket notation and macroscopic quantum phenomena had only been linked very discreetly, I put them back, as those are useful articles. Interpretations of quantum mechanics is of course important, but it is already prominently linked, so I left it out. Relational quantum mechanics is also out, because we don't want to link all interpretations in "see also", and this is not a particularly accepted or well-developed one.

I also took the chance to remove fractional quantum mechanics (I'll AfD this crap when I have the time), quantum dynamics (perfectly legit, but the article is content-free), and spherical basis.

Finally, please don't take my opinion here as absolute. This is a matter of editorial discretion, not of technical content, and you can't in any case verify that I'm actually a physicist. Tercer (talk) 13:39, 9 July 2021 (UTC)

Phase space formulation and Regularization (physics) look a bit odd — not that they're completely irrelevant to the topic, but why mention those two things specifically? I've no firm opinions about the "See also" section at present; as long as it's not a total junk drawer and/or advertising fringe topics that ought to be deleted, it's probably not a big deal. XOR'easter (talk) 17:05, 10 July 2021 (UTC)

@Tercer: support your cleanup. I'd be glad to help AfD fractional quantum mechanics, total self-promotion. I'm seeing this more and more on WP, academics inventing terms and creating articles to get exposure for their work. --Chetvorno^TALK 18:08, 10 July 2021 (UTC)

There's also Fractional Schrödinger equation and Variable-order fractional Schrödinger equation (the latter having apparently been created by the coauthor of its only reference). I'm never eager to take these vanity/pet project articles to AfD, thanks to the seeming inevitability of "well, it has footnotes, so it must be notable" comments, but at some point it becomes necessary. XOR'easter (talk) 18:23, 10 July 2021 (UTC)

Well, I know what you mean. I've run across several examples in my field of electrical engineering; and I haven't seen one AfD'd yet. That's why I offered to help. I think we need to defend WP against this, we can't have it turning into a linkfarm for aspiring postdocs. --Chetvorno^TALK 19:31, 10 July 2021 (UTC)

If AfD is a no-go, I'm wondering if there are other ways to deal with these pages?

• Have you ever used the WP:Conflict of interest/Noticeboard?
• WP:PSTS requires articles be based on secondary sources, not primary, which these aren't. So editors could delete the text of the article as unsourced. Then the page could be redirected to a legitimate existing article, such as Fractional calculus. Then in a year or so, an RfD could be submitted, on the ground that there is no reference to the term in the target article.
• A similar process of redirecting the article could be started on the grounds of lack of notability, WP:undue weight.

--Chetvorno^TALK 19:56, 10 July 2021 (UTC)

I researched a bit more, and there are independent sources on fractional quantum mechanics, so an AfD will probably not work. I just edited it a bit to make it less promotional, and redirected both articles found by XOR'easter to it. Tercer (talk) 18:47, 11 July 2021 (UTC)

And of course the redirect was contested by the author. Now Polyamorph has AfD'ed everything. Tercer (talk) 14:28, 12 July 2021 (UTC)

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Hi,

I'm not a regular editor of articles on wikipedia - so please excuse me if I say/do something that is a classic newbie mistake. I assure you it's not intentional!;-)

I made an edit to the quantum mechanics page a while back (Revision as of 00:56, 5 March 2020) where I suggested making it clear that quantum mechanics didn't just apply at the small/atomic scales, but at all scales.

The suggested revision read:

"Classical physics, the description of physics that existed before the formulation of the theory of relativity and of quantum mechanics, describes many aspects of nature at ordinary (macroscopic) scale. Quantum mechanics explains the aspects of nature at ordinary (macroscopic) scales but extends this description to the small (atomic and subatomic) scales."

The details for the rationale for that original edit are explained in the original edit here: https://en.wikipedia.org/w/index.php?title=Talk:Quantum_mechanics&oldid=prev&diff=943986158. This edit was accepted at the time (thanks!).

However, subsequently, it seems that the edits which I made were changed by "Aera23 at 01:24, 16 May 2020 (Clarity edits to the 'lead' section)", https://en.wikipedia.org/w/index.php?title=Quantum_mechanics&oldid=956919287 to:

"Classical physics, the description of physics that existed before the theory of relativity and quantum mechanics, describes many aspects of nature at a. ordinary (macroscopic) scale. Quantum mechanics also explains the aspects of nature at a small (atomic and subatomic) scales".

This wording has persisted, essentially intact, to the present page today wikipedia page (https://en.wikipedia.org/wiki/Quantum_mechanics):

"Classical physics, the description of physics that existed before the theory of relativity and quantum mechanics, describes many aspects of nature at an ordinary (macroscopic) scale, while quantum mechanics explains the aspects of nature at small (atomic and subatomic) scales, for which classical mechanics is insufficient."

I do not think that this present wording is accurate (for the same reasons that I explained in my original edit). I am not sure whether Aera23 intentionally intended to change the meaning of the text or whether it just "sounded better" to their ear, however, the wording to which Aera23 changed the text makes it seem like there are two different kinds of physics and that quantum mechanics applies only to the small (atomic and subatomic) scales - not at all scales (large and small). Physicist Brian Cox and Jeff Forshaw have also recently pointed out this very fact in the book "the quantum universe" (https://en.wikipedia.org/wiki/The_Quantum_Universe) where they state:

pg 16. "We do mean that, by the way - Newton's laws are heading for the bin because they have been exposed as only approximately correct. They work well in many instances but fail totally when it comes to describing quantum phenomena. The laws of quantum theory replace Newton's laws and furnish a more accurate description of the world. Newton's physics emerges out of the quantum description, and it is important to realize that the situation is not 'Newton for big things and quantum for small': IT IS QUANTUM ALL THE WAY" (emphasis mine)

and on pg 74. "This specific arrangement corresponds to a particle initially at rest within a certain region of space - a sand grain in a matchbox, for example. Although we discovered that the particle will most likely not remain at rest, we also discovered that for large objects - a grain of sand is very large indeed in quantum terms - this motion is completely undetectable. So there is some motion in our theory, but it is motion that is imperceptible for big enough objects. Obviously we are missing something rather important, because big things do actually move around, and remember that QUANTUM THEORY IS A THEORY OF ALL THINGS BIG AND SMALL." (emphasis mine)."

In light of this, I would like to change the current text:

"Classical physics, the description of physics that existed before the theory of relativity and quantum mechanics, describes many aspects of nature at an ordinary (macroscopic) scale, while quantum mechanics explains the aspects of nature at small (atomic and subatomic) scales, for which classical mechanics is insufficient."

to:

"Classical physics, the description of physics that existed before the theory of relativity and of quantum mechanics, describes many aspects of nature at ordinary (macroscopic) scale. Quantum mechanics explains the aspects of nature at ordinary (macroscopic) scales but extends this description to the small (atomic and subatomic) scales."

Please let me know what you think. Thanks! — Preceding unsigned comment added by Papaneeds (talk • contribs)

Hi! Thanks for commenting. A few thoughts: first, the introduction is meant to summarize concisely the material that the rest of the article discusses in more depth. Second, we try not to base our articles on pop-science books, no matter who wrote them, since the popularization process inevitably simplifies things. Third, more specifically, it seems to me that the point is adequately covered by the following sentence of the introduction, which talks about classical physics being derived from quantum mechanics as an approximation valid at large (macroscopic) scale. So, while I'm open to revising the intro, I think the proposed change needs more workshopping before it can be implemented. (There are advocates of ideas like Ghirardi–Rimini–Weber theory in which the world is not quantum all the way up, but that's a marginal enough idea that we don't need to bring it up in the opening paragraphs of the "quantum mechanics" article.) It's worth thinking about, though, so thanks again for bringing it up. XOR'easter (talk) 20:17, 29 August 2021 (UTC)

Hi XOR'easter! Thanks for the speedy and informative response. May I address your thoughts in turn?

First, about the introduction. I agree, it should be concise and pithy. I'd suggest that the difference between the current wording (46 words) vs the proposed wording (48 words), while not totally insignificant, does not overly expand the introduction. And, importantly, it puts front and centre the crucial point that quantum mechanics is not just for "small" things.

As to your second point - I do understand your reluctance to use a pop-science book as a source - you are correct, they do sometimes over-simplify things (though perhaps not in this case;-). I could list many "real" physics books and articles that make the same point (especially in Solid State Physics (where macroscopic phenomena such as metals, semiconductors and insulators, and the phenomena of "colour" are totally incomprehensible without quantum mechanics, as well as Chemistry (where the periodic table is incomprehensible without quantum mechanics), and original research articles - the fact that atoms don't collapse to points by electrons radiating energy and spiraling in to the nucleus (reducing the earth to the size of a basketball)). However, putting a whole list of references into the introductory section might be a bit overwhelming (detailed references to phenomena such as these are perhaps more appropriate later in the article).

As to your third point - you are correct that the misconception about quantum mechanics only applying at the small scale is somewhat clarified later in the article where there are several statements about quantum mechanics applying at all scales, such as: "Most theories in classical physics can be derived from quantum mechanics as an approximation valid at large (macroscopic) scale." and the entire section on "Relation to other scientific theories: classical mechanics". Nonetheless, I believe that the article could be improved by avoiding the "small scale" trap right off the bat.

I think the thing that really sticks in my craw about the current wording is the "while" word in the sentence: "...describes many aspects of nature at an ordinary (macroscopic) scale, WHILE quantum mechanics explains the aspects of nature at small (atomic and subatomic) scales..." (emphasis mine).

Using the word "while" makes it seem like, on the one hand there is classical physics for big things while on the other hand there is quantum mechanics for small things and that somehow there are two different kinds of physics. Putting this wording in the introduction section I believe only fosters confusion about this point.

I'm not sure if my proposed wording of:

"Classical physics, the description of physics that existed before the theory of relativity and of quantum mechanics, describes many aspects of nature at ordinary (macroscopic) scale. Quantum mechanics explains the aspects of nature at ordinary (macroscopic) scales but extends this description to the small (atomic and subatomic) scales."

makes the point any better? Is there something in particular that you find confusing, and/or overly verbose, and/or unsubstantiated, and/or overly pedantic about the proposed wording? Do you have any suggestions as to a better wording?

If references are required my favourite Solid State Physics book is, "Solid State Physics" by Ashcroft and Mermin, Brooks Cole; 1st edition (Jan. 2 1976)".

A great article on how quantum mechanics explains the macroscopic phenomena of colour is https://www.itp.uni-hannover.de/fileadmin/itp/emeritus/zawischa/static_html/basiq.html

A good (introductory) article on why electrons don't fall into the nucleus is https://chem.libretexts.org/Bookshelves/Physical_and_Theoretical_Chemistry_Textbook_Maps/Supplemental_Modules_(Physical_and_Theoretical_Chemistry)/Quantum_Mechanics/09._The_Hydrogen_Atom/Atomic_Theory/Why_atoms_do_not_Collapse

And, in the same vein, a good article on the quantum explanation for the periodic table (and hence much of chemistry, which is what our macroscopic world is largely dependent on) is: https://chem.libretexts.org/Bookshelves/General_Chemistry/Map%3A_Chemistry_-_The_Molecular_Nature_of_Matter_and_Change_(Silberberg)/08%3A_Electron_Configuration_and_Chemical_Periodicity/8.02%3A_The_Quantum-Mechanical_Model_and_the_Periodic_Table

Anyhow, how would you like to proceed? Is there some specific action you would like me to take in order to be able to change the wording to my proposed wording? Please let me know. — Preceding unsigned comment added by Papaneeds (talk • contribs)

Thanks again! One minor note of procedure: it helps clarify discussions if you sign your comments. Just add four tildes, and the software will automatically replace that with your user name and a time-stamp when you save your edit. As to the content: I guess the "while" just isn't sticking in my craw as much as it is yours. Currently, the intro says that classical physics describes many aspects of nature at an ordinary (macroscopic) scale, and then transitions to saying that quantum physics explains the aspects of nature at small (atomic and subatomic) scales (emphasis added). The transition from many to the seems to load the sentence in favor of quantum physics being more all-inclusive and generally just better. That's how it reads to me, at least (and a lot of this will come down to matters of taste). I wouldn't mind splitting that sentence. Your suggestion isn't bad at all, but I don't like losing the "for which classical mechanics is insufficient" part; without that, the "extends" makes quantum physics sound like a mere elaboration of the classical physics that went before. I have to run now, but I'll definitely keep thinking about it, and hopefully we can get some feedback from other editors here too! Cheers, XOR'easter (talk) 20:43, 30 August 2021 (UTC)

What's meant here is that *our description* of Nature in quantum physics *starts* at the scale of elementary particles and atoms (but does not necessarily end there: our colorful crystals are "infinite", superconductivity is a macroscopic quantum phenomenon, and so on). In classical physics our description cannot be this grainy; once we start noticing the (sub)atomic degrees of freedom classical physics fails. We like to think that things are classically deterministic at the macroscopic scale (as opposed to quantum-mechanically probabilistic) and you will hardly ever solve the Schroedinger eq. to find the probability of your car tunneling through the garage door. Yes, quantum physics applies there, but it's as "useless" as classical physics at the atomic scale. Thus "quantum mechanics explains the aspects of nature at ordinary scales but extends this description to the small scales" is not how we use quantum mechanics, it's quite the opposite. If anything needs to be changed, I think we should find a better wording to say that our descriptions in quantum physics *start* at the atomic scale. Ponor (talk) 02:14, 1 September 2021 (UTC)

I think Papaneeds does have a good point. The article right now is misleading, it does give the impression that quantum mechanics is for microscopic phenomena, and classical mechanics is for macroscopic phenomena, which is of course incorrect. Not only the sentence they pointed out, but also the very first sentence Quantum mechanics is a fundamental theory in physics that provides a description of the physical properties of nature at the scale of atoms and subatomic particles, and the second sentence of the overview section It is typically applied to microscopic systems: molecules, atoms and sub-atomic particles. It has been demonstrated to hold for complex molecules with thousands of atoms, but its application to human beings raises philosophical problems, such as Wigner's friend, and its application to the universe as a whole remains speculative. Everything written in the article is true, but does give the wrong impression.

My suggestion for improving the situation is simple: just remove the part while quantum mechanics explains the aspects of nature at small (atomic and subatomic) scales, as it contains the problematic "while" and repeats what was already stated in the previous paragraph. I went ahead and just did it. I also removed the implication that relativity is not part of classical physics; sometimes it is classified as classical, sometimes not, but was besides the point here, as relativity alone cannot deal with atomic phenomena either. Tercer (talk) 09:15, 1 September 2021 (UTC)

I'm fine with this edit. It has the added advantage of being more concise. XOR'easter (talk) 17:40, 1 September 2021 (UTC)

I also think that the edit is good and improves the article. Thanks! Papaneeds (talk) 12:43, 2 September 2021 (UTC)

I'm also okay with the current edit of the intro, although "collection of theories" is a little clunky. --Chetvorno^TALK 22:00, 3 September 2021 (UTC)

For the record, I appreciate Papaneeds collegial spirit and the points he made above, but I am strongly opposed to the original proposed wording change:

"Quantum mechanics explains the aspects of nature at ordinary (macroscopic) scales but extends this description to the small (atomic and subatomic) scales."

This would have been very confusing for general readers, who would have been led to think that the quantum properties detailed in the next paragraph wave-particle duality and uncertainty principle, were observable in macroscopic objects. The presence of Planck's constant in the Planck-Einstein relation, De Broglie equation, the Heisenberg uncertainty relation, and the Schrodinger equation pretty much guarantees that quantum properties are only observable in objects 'small' on a human scale. As Papaneeds mentioned, as a special exception quantum properties are observable on a large scale in currents of bosons (particles obeying Bose-Einstein statistics) such as superconductivity, superfluidity, and coherent light beams, but that is only because Bose statistics encourage large numbers of bosons to be in the same quantum state. In these phenomena it is the constituent tiny particles which exhibit the quantum properties, there just happen to be a lot of them in a coherent state. The only reason the wavefunction interference pattern is visible in the double slit experiment is that it is made up of uncounted trillions of individual photons in the same state. To observe true quantum wave-particle duality in the experiment you have to turn the intensity down until a single photon is passing through the slits at a time, in which case the interference pattern is not observable without sensitive instruments. --Chetvorno^TALK 23:23, 3 September 2021 (UTC)

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In the example section the use of a rather than ${\displaystyle a}$ causing confusion. We see that as we make a smaller the spread in position gets smaller, but the spread in momentum gets larger. Conversely, by making a larger we make the spread in momentum smaller, but the spread in position gets larger. This illustrates the uncertainty principle.

Consider changing to: We see that as we make ${\displaystyle a}$ smaller the spread in position gets smaller, but the spread in momentum gets larger. Conversely, by making ${\displaystyle a}$ larger we make the spread in momentum smaller, but the spread in position gets larger. This illustrates the uncertainty principle. 95.17.142.38 (talk) 14:51, 21 October 2021 (UTC)

 Done. See [8]. - DVdm (talk) 14:55, 21 October 2021 (UTC)

I have a problem with the section https://en.wikipedia.org/wiki/Quantum_mechanics#Free_particle. We see the equation for the Hamiltonian, :${\displaystyle H={\frac {1}{2m}}P^{2}=-{\frac {\hbar ^{2}}{2m}}{\frac {d^{2}}{dx^{2}}}.}$

That last bit, :${\displaystyle {\frac {d^{2}}{dx^{2}}}.}$ is a second derivative. Second derivative of what? The relevant function needs to added.Saintonge235 (talk) 22:51, 22 January 2022 (UTC)

@Saintonge235: To answer your question, the Hamiltonian is a differential operator, as made clear earlier in the article, so the right hand side is not a second derivative of anything. No corrections needed. –LaundryPizza03 (dc̄) 23:04, 22 January 2022 (UTC)

@Saintonge235: Considering that the GA nomination was successful, I moved this to the bottom of the talk page. Sorry for all the pings. See above for the answer. –LaundryPizza03 (dc̄) 23:10, 22 January 2022 (UTC)

so, the schrodinger equation on the template for quantum mechanics is: ${\displaystyle i\hbar {\frac {\partial }{\partial t}}|\psi (t)\rangle ={\hat {H}}|\psi (t)\rangle }$ why is it using partial derivatives when psi only has one variable (which is t) can someone change it to a d?Itsame,Jacob87372 (talk) 01:26, 22 March 2022 (UTC)

I guess whoever wrote it was thinking about the Schrödinger equation in position space, where the derivative really must be a partial one. Now in the equation in the template ${\displaystyle |\psi (t)\rangle }$ is not a function of position, so you can use a total derivate without any problems, but a partial derivative is still correct. You can change it if you want. Tercer (talk) 10:13, 23 March 2022 (UTC)

This opening provides all the wrong explanations that lead people to misunderstand QM. In its current form, it is only speaking to people who already know what quantum mechanics is, and doing a terrible job at it.

This is a proper definition that should head the article: "Quantum mechanics is a fundamental theory in physics that describes the physical properties of atoms and subatomic particles by predicting how clouds of subatomic particles interact. It is the probabilities of interacting particles whose fuzzy interactions act as a facilitating mechanism of all matter. (See Quantum Statistical Mechanics.) It is the foundation of quantum chemistry, quantum field theory, quantum technology, and quantum information science." This allows the lay person to get a generalized overview in as few words as possible.

But the only mention of probabilities here is "probability amplitudes" which is a specialized term requiring an existing and well-established understanding of statistical mechanics to know what it means.

The article fails to explain that Planck introduced statistical theory into physics equations in order to explain how infrared light passes through solid objects (black body radiation). Then Diraq picked it up and made the statistical probabilities a whole fundamental science in itself. In fact, the article needs a proper brief summarized history of quantum mechanics section pointing to the History of Quantum Mechanics page and explain its relationship to statistical mechanics.

Without these things, the layman is left scratching his head. 2604:CB00:52D:3200:1540:F5CF:42AD:20B0 (talk) 13:31, 10 June 2022 (UTC)

Hey there, thanks for bringing this to the talk page. I understand where you're coming from - there's a fair bit of technical language in the lead - but I don't think it needs changing. In physics, sacrificing precision in language for 'readability' can lead to the exact misunderstandings you speak of. Sure, you can water things down in primer texts and pop science books, but this article is meant to be an accurate and complete overview of the subject.

The job of the lead of an article is to offer a succinct and accurate overview of the key points of the article. I think the current lead does this well.

I also take issue with your suggested changes: 'clouds of subatomic particles' is an ambiguous, and in this context, misleading phrase. Do you mean clouds of (many) particles? Or the 'probability clouds' of single (or few) particles? Also, QM applies not just to subatomic particles but also to atoms.

'It is the probabilities of interacting particles whose fuzzy interactions act as a facilitating mechanism of all matter.' This sentence is a load of waffle, frankly. In particular, 'probabilities of interacting particles' is ambiguous. A particle doesn't have a 'probability'. And 'a facilitating mechanism of all matter'??? I'm sorry, but this is incomprehensible. Mechanism to do what? What does facilitating mean here?

If you want a watered-down lead comprehensible to the lay person, neither the current lead or your suggested replacement are appropriate. In fact, if you want to see what this would look like, I suggest you take a look at the article on quantum mechanics on Simple English Wikipedia.

I hope what I've said makes some sort of sense; if not, I'm happy to discuss this up to a point. — Jumbo T (talk) 14:25, 10 June 2022 (UTC)

I agree with Jumbo T, the changes proposed by the IP, while well intentioned, would not be an improvement --Chetvorno^TALK 14:41, 14 July 2022 (UTC)

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The elementary term for this field of science, object is not linked. I would change it to the correct terminology: "physical object" and include a link to its Wikipedia article here: https://en.wikipedia.org/wiki/Physical_object#Quantum_mechanics for those that have a limited knowledge of an object like I did. When I tried to find the definition I got this: Something perceptible by one or more of the senses, especially by vision or touch; a material thing. A focus of attention, feeling, thought, or action. A limiting factor that must be considered. This is in contrast to Quantum Mechanics. Our senses cannot detect Quantum objects. So what are they defined as? Quaantum Mechanics Vocab: In quantum mechanics an object is a particle or collection of particles. Until measured, a particle does not have a physical position. A particle is defined by a probability distribution of finding the particle at a particular position. There is a limit to the accuracy with which the position and velocity may be measured. A particle or collection of particles is described by a quantum state.

These ideas vary from the common usage understanding of what an object is.

String theory In particle physics, there is a debate as to whether some elementary particles are not bodies, but are points without extension in physical space within spacetime, or are always extended in at least one dimension of space as in string theory or M theory. A marked difference and major requirement for understanding the entire first paragraph.

IMPORTANT I put "quantity" in bold so many times to show that "qualities" is so overlooked part of Quantum Mechanics as is overlooked here. Yet the first paragraph states that Quantum means "the description of the physical properties". This is not quite right. The etymology of quantum is translated from latin to "how much", or, an amount. Therefore the name Quantum mechanics was chosen as it deals with numbers. But numbers, math, is a language that allow us to easily describe the properties of and how physical things work.

The phrase "and other quantities" should be changed to quantities that are known. This seems to have been written by someone either lazy or has incomplete knowledge. I do not know what quantitative elements are known in quantum mechanics. So, if there are "other quantities" that are referred as such, because they are known to exist but have no name, then explain this better. If there are other other quantities that are not listed, then why are these "other quantities" not listed? This is how it should be written: "...energy, momentum, angular momentum, new_entry, and final_entry quantities". Move the term quantization here as it makes more logical sense to have it next to quantum mechanic's quantities. Both quality and quantity should be part of this paragraph, together. Add link to the article defining "qualitative". Make sure to write a quick sentence that qualitative (here: https://en.wikipedia.org/wiki/Qualitative_property) is a close and important term that has been overlooked and will expand the total knowledge on what is being talked about, especially in this paragraph. This is where quantities are used to show the qualities. We see long, crazy equations and it looks alien and super hard. But it is actually very simple. The idea behind it is revvolutionary, but the math is actually an elegant, simple description. This is also true for Newtownian physics; see: https://en.wikipedia.org/wiki/Philosophi%C3%A6_Naturalis_Principia_Mathematica

I agree that the first part may need a rewrite. Here is an idea, everyone write to Neil DeGrasse Tyson to write it. I know, he is an astrophysist, but one of the best people on earth to get anybody to understand and enjoy: https://www.haydenplanetarium.org/tyson/contact.php I only ask this because Wikipedia has is ups and downs. Having people get the best writers to contribute will be worth more than gold.

Thanks, all. (Sorry for all the editing. I'm rusty to using this platform.) Austemagne (talk) 15:25, 14 July 2022 (UTC)

 Not done I don't see how linking to the short, choppy, and unsourced text at Physical_object#Quantum_mechanics would be anything more than a distraction. XOR'easter (talk) 16:08, 14 July 2022 (UTC)

@Austemagne: Thanks for your overview of the article with fresh eyes, and your perceptive comments. My feeling is that the changes you suggest would not be an improvement. The introduction is difficult to write because it is supposed to be understandable by general readers (WP:MTAU, WP:EXPLAINLEAD) but also an accurate summary of a very technical subject (MOS:INTRO))

• The emphasis on “quantities” as opposed to “qualities” is appropriate because QM is a quantitative theory. The main difference between quantum and classical physics is limitations on the ability to measure quantities.
• Linking “object” is unnecessary. It is being used in a descriptive rather than a formal sense
• Mentioning string theory in the intro is unnecessary and WP:undue weight
• I would welcome Neil DeGrasse Tyson contributing to the article

--Chetvorno^TALK 19:03, 14 July 2022 (UTC)

Hi -- I'm happy that the article links to my book The Modern Revolution in Physics under "External links." However, the more up-to-date version of the book would be Modern Physics, which is at this URL: http://www.lightandmatter.com/mod/ . I would update the link myself, but the article is locked. Thanks! -Ben Crowell — Preceding unsigned comment added by 2603:8000:8900:6E00:F161:CB6C:7FF:AB1C (talk) 00:55, 5 February 2023 (UTC)

@Logic314: Another citation is needed. Cannot use the Bell citation by itself to back the claim of nonlocality. We would need another source. It's possible to cite other sources. -- Ancheta Wis   (talk | contribs) 08:51, 20 May 2023 (UTC)

I don't think we need to say more about Bell's theorem in this article than we already do. XOR'easter (talk) 16:25, 20 May 2023 (UTC)

If you are not aware that Bell's Theorem does indeed prove nonlocality for tiny-scale quantum mechanics, I suggest you do some research on the Web to learn about it for yourself. There are many misconceptions about QM in circulation, and it is not a burden on WP editors to prove facts to other editors. David Spector (talk) 13:44, 9 August 2023 (UTC)

My problem is with the following:

"By 1930 quantum mechanics had been further unified and formalized by David Hilbert, Paul Dirac and John von Neumann with greater emphasis on measurement, the statistical nature of our knowledge of reality, and philosophical speculation about the 'observer'."

The single citation given for this sentence only emphasises von Neumann's contributions. While this work was based on the mathematics of Hilbert (i.e. Hilbert spaces), I have not found any sources to back up the claim that Hilbert himself was key to developing quantum mechanics during its later stages.

Proposal: remove Hilbert's name from this sentence (unless a reference can be found to support up this claim). Instead add something about the importance of his earlier mathematical innovations. 138.38.94.186 (talk) 11:24, 15 June 2023 (UTC)

Hilbert's contributions were abstract and influenced the physicists. The respect and esteem with which Born (and other close associates like v.Neumann) held Hilbert comes to mind, but Born's formulation of inner product for QM (B. formulated it in the 1920s) wasn't rewarded until 1955. Perhaps Hilbert's influence on Born and von Neumann might be the subject for an appropriate citation (from a historian of science). Or perhaps some parentheses, such as 'By 1930 quantum mechanics had been further unified and formalized by Max Born, Paul Dirac and John von Neumann (who were themselves influenced by David Hilbert)'.

I forgot Schwarz inequality. But this goes outside QM. There are other applications. (Think Signal processing in electrical engineering) --Ancheta Wis   (talk | contribs) 16:20, 15 June 2023 (UTC)

Hilbert contributed the mechanism that makes reasoning about measurements in the tiny scale easier, so I'd rather his name be retained. But it is also true that he was not one of the principal developers of QM. David Spector (talk) 13:48, 9 August 2023 (UTC)

https://en.wikipedia.org/wiki/User:Proshno has been attempting to edit this article to claim that local realism may still obtain in quantum mechanics. However, this unusual claim is not backed up with any reliable references. This edit (https://en.wikipedia.org/w/index.php?title=Quantum_mechanics&diff=next&oldid=1169333352) cannot be allowed, per WP policies. Let's discuss here instead of edit-warring. David Spector (talk) 13:41, 9 August 2023 (UTC)

Superdeterminism, which Proshno was adding, is a theory that would explain quantum mechanics' violation of Bell's inequality without giving up local realism:

• "Another weak link in Bell's argument is associated with the assumption of statistical independence. The strategy is to allow systematic violations of statistical independence in favor of 'super-deterministic' theories..."Knox, Wilson, The Routlege Companion to Philosophy in Physics p.190
• "...Bell nonlocality can be demonstrated as soon as the processes that choose the inputs and those chosen by the players are independent. The strongest way to deny this measurement independence is superdeterminism..." Scarani, Bell Nonlocality, p.20

"The strongest way to deny this measurement independence..." Anyone can spin a conjecture up to speed and deny any scientific knowledge whatsoever. It takes real intelligence and ethics to refrain from doing so. Measurement independence has been validated by every experiment in quantum mechanics throughout its history. It seems to me foolish to give serious concern to this, or to local realism itself, and deny all the experiments performed up to now, or the theories supported by them. I'm not opposed to conjecture, but asking that conjecture be reflected in a basic science article in WP is counter to what I have learned in my ten years as a WP editor. David Spector (talk) 21:12, 9 August 2023 (UTC)

• Bertleman, Zeilinger, Quantum (Un)speakables: Half a century of Bell's theorem, p.135
• "...in order for our discussion to be complete, it is necessary to mention an argument [superdeterminism] some have advanced for the purpose of avoiding the nonlocality condition. However... the proposed idea is not only artificial, but also quite radical and unwarranted" Hemick, Shakur, Bell's theorem and Quantum Realism, p.54
• "By proposing that the theory underlying quantum mechanics be both local and deterministic, superdeterminism removes both fundamental incompatibilities at once..." Adlam, Foundations of Quantum Mechanics, p.17

However I'm not sure it has sufficient support among physicists to merit Proshno's statement. --Chetvorno^TALK 18:52, 9 August 2023 (UTC)

I think it's okay for WP to mention the frontiers of thinking about QM, in the proper context. But in the context of a basic article about QM, I don't think that all conjectures need to be included. Certainly all major theorems and facts need to be included. Nonlocality, along with quantization, linear superposition, and wave/particle duality, is at the basis of QM. It is these basics that need to be in this article. Let's put the conjectures and ontological interpretations in a small section, with a link to an article that focuses just on them.

Our commonsense intuition, which validates local realism, is certainly valid in large scales, all the way up. But it is just as certainly misleading when applied to the very tiniest of scales. Let's maintain balance, and explain what has actually been discovered about QM, both experimentally and theoretically, and leave the interpretations and conjectures for another article. Otherwise, we run a serious risk of misleading those wishing to learn what is really known about QM. David Spector (talk) 19:40, 9 August 2023 (UTC)