This is a list of interesting articles on wacko theories; unfortunately, these attract wacko and crank edits, and various shades of subtle vandalism. These articles should be watched for inappropriate edits.

The list of pseudoscientific theories is a target of frequent crank edits. So are many articles in Category:Pseudoscience; physics topics should be categorized in Category:Pseudophysics.

Famous historical blunders[edit]

Blunders involving famous academicians and institutes.

Semi-legit topics[edit]

Compelling ideas that attract both legit academic and crank/original research.

Discussion for Wikipedia:Pages needing attention/Physics[edit]

Notice to members of WikiProject Physics: Pages needing attention (PNA) is being reconfigured as a bot-maintained list of cleanup, expansion, and expert attention requests, as well as one-stop shopping for relevant portal, wikiproject, category, and stub category links. As such, comments on PNA must be moved to talk pages or to wikiprojects. As such, the following are moved here. Alba 12:56, 10 April 2006 (UTC)Reply[reply]

Listed since December 2005 CE, most recent first

New Articles:

have all been created and written by two users which may or may not be the same person:
Cabrer7 (Contributions) and
137.207.80.65 (Contributions)
The sentence that triggered my suspicions came from the introduction to the Paravector article,
This name was given by J. G. Maks, Doctoral Dissertation, Technische Universiteit Delft (Netherlands), 1989.
JabberWok 17:08, 9 December 2006 (UTC)Reply[reply]
This is a confusing one. It doesn't seem as though there is any disagreement about the physics of the range. The effect, which everyone seems to agree on, is that there is a nuclear force with a short range. But some users seem to draw a distinction between the nuclear force, which I guess they consider to be carried by pions (which are massive and unstable) and some abstract notion of chromodynamics, where the carrier is the gluon (which is massless and stable). I don't know if this distinction is standard among lattice gauge theorists.
The trouble with this abstract notion of chromodynamics is that experimentally the gluons appear to be confined. If this can be proved theoretically, whoever does the proof wins a million US dollars from the Clay foundation. But the experimental evidence at the temperatures and pressures typically encountered on Earth (less than 5 trillion degrees or so) is pretty overwhelming that the gluons are indeed confined. So, at everyday temperatures and pressures, there isn't any force mediated by gluons because gluons can't ever get themselves free. Effectively (and approximately), they're always bound to pions. So this distinction that the authors create between chromodynamics and the nuclear force is really all a bit artificial, there's only a nuclear force (except for very extreme environments, such as perhaps the interior of a neutron star and for brief periods in some laboratories) since pions can freely move around transmiting forces (in the 10^-23 seconds before the decay) whereas gluons are only some abstract virtual internal excitation.
Besides the range, the scaling has also been changed to 1, a scaling of 1 and range infinite would be correct if one considers, as was popular during the early 70s (but replaced by the chromodynamics in the standard model) the action of the strong force on two particles to be described by a string which connects them. However, both the 1 and the infinity fail even in this picture when one realizes that such strings would break when, for example, a quark and antiquark pair create in the middle. This effect is refered to as screening, and I feel that it invalidates the recent changes made to the table.
Perhaps to resolve these two issues one can specify that the table is only valid in one particular region of the QCD phase diagram, say, temperatures below 5 trillion and reasonable pressures, and put back the old values of the scaling and range?JarahE 01:07, 18 April 2006 (UTC)Reply[reply]
My understanding was that a significant amount of the lift produced over an airfoil was due to the Coandă effect, not just Bernoulli's principle. Among other things, this is why it isn't impossible for stunt aircraft to fly upside-down. However, I'm not an aerospace engineer, so it's quite possible that I'm wrong about the degree to which the effect is relevant under normal flying conditions. --Christopher Thomas 22:24, 1 April 2006 (UTC)Reply[reply]
Is there an aerospace engineer in the house? ---CH 00:50, 2 April 2006 (UTC)Reply[reply]
Maybe the recurring epiphanies people are having are due to the fact that it's a perfectly viable reflection of reality? Denial ain't just a river in Africa. (Sorry I'm just having a ball with this thing, nothing personal.) David Ashley 05:00, 29 December 2005 (UTC)Reply[reply]
The reasons why this interpretation isn't accurate are presented at Schwarzschild metric. I'm sure any of the GR physicists lurking here can give you a more detailed explanation. Short version is that the visual effect is an illusion caused by the fact that light emitted near the horizon can take an arbitrarily long time to escape the hole, and that the mathematical effect that gives you the "frozen star" interpretation is an artifact of the coordinate system Karl Schwarzschild used the first time he did the analysis. This is discussed in detail at Schwarzschild metric. I've given this overview enough times to get really sick of doing it, so we need something in the article that explains it more convincingly (showing it, as opposed to saying it, because people apparently don't want to just take the word of all of the textbooks on the subject). --Christopher Thomas 17:45, 29 December 2005 (UTC)Reply[reply]
  • Entering a black hole
The paragraph states: "A black hole's gravity as described by the Theory of Relativity causes a number of peculiar effects. An object approaching a simple causes a number of peculiar effects. An object approaching a simple Schwarzschild-type (non-rotating) black hole's center will appear to distant observers as having an increasingly slow descent as the object approaches the event horizon. This is because photons emitted as the object approaches the horizon take an increasingly long time to escape from the pull of the black hole to allow the distant observer to gain information on the object's fate."
This can be interpreted as if the light was slowed down to a speed less than c, which, as to my understanding, is impossible. Instead, I think the effect is due to the time dilation so that successively emitted photons, all well traveling at speed c, arrive at increasing intervals of time because the points at which they were emitted are seen to have an increasing distance in time by the observer though not by the emitter.
Could someone whit a really firm knowledge of this subject please have a look at the article and the talk page? 84.160.227.124 11:21, 6 January 2006 (UTC)Reply[reply]
This can be interpreted... is wrong; please see for example Geroch, Relativity from A to B, which offers an excellent nontechnical illustrated discussion of basic Schwarzschild vacuum geometry, focusing on the black hole property (the event horizon) not on the maximal extension, of course. ---CH 17:22, 23 March 2006 (UTC)Reply[reply]
If people took textbook's words for things science wouldn't make very much progress. The arguments above for the existence of black holes rely on general relativity. Here's an argument championed by John Preskill about why this approximation cannot be trusted in the case of black holes. General relativity is a classical approximation to our world, which is valid at energies far below the Planck scale. The validity of this approximation is at best poorly understood in the case of objects falling into a blackhole, because the redshift of the light emitted by such objects goes to infinity as the object approaches the black hole. This means that very high energy physics (above the Planck scale) from the point of view of the infalling object must be understood in order to understand the light which an outside stationary observer measures to be sub-Planckian. In other words, the infinite Doppler-shift invalidates the usual approximation that super-Planckian physics (ie quantum gravity) can be ignored to calculate low energy effects and so it puts in doubt the applicability of general relativity to the horizon, despite the fact that the curvature is quite small at the horizon of a large black hole.
This means that it is very possible that the existence of black holes depends on which quantum gravity theory describes our world, and that in some quantum gravity theories they do not exist (see also fuzzballs). Some of the leading relativistists have proposed in the past that this is the case, see for example Evanescent Black Holes by Curtis Callan, Steven B. Giddings, Jeffrey A. Harvey and Andrew Strominger who proposed that black holes evaporate before they form, which is another version of the scenario criticized above. JarahE 19:18, 25 March 2006 (UTC)Reply[reply]
The debates aren't about whether the GR description of black holes is completely accurate - it's assumed by most scientists that it _isn't_, and this is prominently noted in the article. The problems occurring are with misinterpretations of the _GR description_, especially in the specific ways outlined above. The majority of the black hole article is concerned with the GR description of black holes, as it's the best uncontroversial description we have to date. The reason it's listed here is that we're getting people regularly showing up saying "statement X about (GR) black holes is incorrect because of (handwaving argument)!", and not taking sketched explanations or "read this stack of references" for an answer.
Does this make clearer what these threads are about? --Christopher Thomas 07:08, 29 March 2006 (UTC)Reply[reply]
Ok, yeah I admit I was playing devil's advocate. I agree with you that people who say that GR and black holes are inconsistent have a faulty argument, and that obviously such faulty arguments shouldn't be put on the page.
But at the same time, I think a more serious problem among people who should know better is that they think that black holes must exist in the quantum theory because the curvature is small near the horizon and so quantum effects should be small. But invariably their arguments have a step, like a transformation to Finkelstein coordinates, which is singular and lets the quantum physics back in. I think that as a result people in general aren't cynical enough about black holes. This is compounded by astronomers claiming to have seen them (which of course is impossible, black holes being black and all, they just see cosmic rays so intense that were GR to be a valid description would indirectly imply the existence of a black hole.) In my opinion this skepticism should be conveyed at least on the trans-Planckian problem page, if not on the black hole page. JarahE 18:10, 29 March 2006 (UTC)Reply[reply]
References to this article have been added to a large number of other articles by Intangir (talk · contribs). Vetting some of these additions might not be a bad idea. --Christopher Thomas 19:45, 26 December 2005 (UTC)Reply[reply]
I find the current state of the article "acceptable" from the physics point of view. Last I looked at it, it was not cranky, and discussed legit physics in a legit way. I'd even suggest de-listing it here; while the article could be improved, its not (currently) bad. (It may, however, become the target of the pseudosciene crowd, and thus should be watched over). linas 21:29, 29 December 2005 (UTC)Reply[reply]
If we can get one or two additional people signing off on it, then it should be safe to de-list it and remove its "disputed" template. Hillman (talk · contribs) should probably be one of these, as he'd had several concerns about the article's content. --Christopher Thomas 22:00, 29 December 2005 (UTC)Reply[reply]
I think I addressed the only factual accuracy concern which Hillman actually stated. In fact, I just deleted the disputed content. However, I'd rather not have it un'disputed' until Hillman has had a chance to respond with any potential new factual accuracy complaints. Also, both of us have plenty of non-fact-oriented issues with the current state of the page, and it will probably have a clean-up tag for some time. However, this can probably be delisted from here after Hillman comes back from wikivacation. --Intangir 02:47, 31 December 2005 (UTC)Reply[reply]

Commented on within the past month

"I think this is a mess but I lack the skills to fix it. Someone who knows QM well might comment" from cleanup >2 months, needs someone knowledgeable on subject. rhyax 06:24, 10 Sep 2004 (UTC)
I've gone over the grammar, and made a suggestion for dealing with it more thoroughly on the article's talk page Bth
I moved this from the "mathematics" section. Paul August 18:33, Jun 5, 2005 (UTC)
I updated this page in the light of quantum decoherence, cleaning up a lot of obsolete and incorrect statements. Dave Kielpinski 00:35, 19 December 2005 (UTC)Reply[reply]
I believe that proximity effect is now in reasonable shape although I still haven't made up my mind about the atomic physics section. Alison Chaiken 05:06, 29 December 2005 (UTC)Reply[reply]


Archive

I'm moving discussion threads from PNA/Physics here once they wind down to reduce clutter. Some of the pages are still in the PNA/Physics list, while others have been removed but have discussion that may still be relevant. Discussion that's no longer relevant to PNA/Physics should be moved to the talk pages of the articles in question. Discussions that are still active should stay on PNA/Physics.--Christopher Thomas 18:40, 26 Jun 2005 (UTC)

Negative energy

(Comments moved here for further discussion/archiving. --Christopher Thomas 18:40, 26 Jun 2005 (UTC))

Various topics relating to quantum mechanics

(Comments moved here for further discussion/archiving. --Christopher Thomas 18:40, 26 Jun 2005 (UTC))

Given that Quantum entanglement now says that the phenomenon has been proven, it's probably OK to add that reference back in. -- Beland 01:27, 19 Aug 2004 (UTC)
One of my objections to that reference was that it was clear that it did not deal specifically with the CH74 test, which is the subject of the article. It could perhaps be given as a ref from Quantum entanglement. However, I suspect it of factual inaccuracy, e.g. in relation to Aspect's experiments. Probably it is no worse than other popular books though.
Incidentally, contradictory though it may seem, "quantum teleportation" does not necessarily (according to Braunstein, one of the experts) involve nonlocal effects. Caroline Thompson 21:18, 22 Aug 2004 (UTC)
I've added a little "background reading" to Bell's theorem. Other popular books can be added here. I don't see the need to suggest other reading from pages such as Clauser and Horne's 1974 Bell test as these are not intended to be treated as anything other than subpages of the Bell's theorem page.
The book list is preceded by a caveat regarding the likely accuracy of the information on actual experiments. This may perhaps be seen as presenting a biased view, but this is only right in the context. Bell's theorem is based on the local realist point of view and it is only fair that the world should be warned that popular books are riddled with mistakes. Contact me for refs.Caroline Thompson 10:45, 24 Aug 2004 (UTC)

Actually, teleportation obeys locality, but not "reality" (in its technical sense). Most popular treatments are pretty poor on this point. This is due to abuse of language in the quantum physics community. It's surprisingly easy to argue most quantum measurement folks out of calling anything "nonlocal" by invoking quantum field theory, widely considered the most successful theory in all of physics, which takes locality as an axiom.

Furthermore, amateur contributors should be aware that local realism and denying the validity of Bell test experiments are views held by a small minority of physicists. Dave Kielpinski 00:28, 19 December 2005 (UTC)Reply[reply]


Cosmology

Crackpot topics[edit]

Ideas lacking a critical foundation. This list may be superfluous, as all of these, and much, much more, already appear in Category:Pseudoscience.

Pages to watch out for[edit]

These are legitimate topics that nevertheless may attract strange edits.

Category