Wikipedia talk:WikiProject Physics/Archive January 2011

Could someone have a close look at what has been happening recently at article Speed of gravity (edit | talk | history | protect | delete | links | watch | logs | views), specially in this addition to the lead by user Antichristos (talk · contribs)? I have added a cn-tag and removed the bolding ([1]), but I think this could need an eye or two. DVdm (talk) 08:09, 19 January 2011 (UTC)

I don't know if that was a reaction to this, but I notice that Xhanthippe already removed the paragraph, which was then immediately restored with 3 refs. Anyway, I'm also wondering about whether the next paragraph ("In relativistic quantum theory...") is at its place in the lead. It looks a bit overwhelming to me. I had removed it previously and had a question about it on the talk page. Some work was done on it by Antichristos, but I'm still not sure whether that thing should be there... - DVdm (talk) 08:49, 19 January 2011 (UTC)

Here is the article in October, before a string of intense editing by Antichristos (and anonymous editors that are probably Antichristos). The old version, though not perfect, seems a lot better to me. Antichristos seems to subscribe to fringe ideas, for example he/she apparently thinks that gravitational radiation is nonsense. I suggest restoring the October version...and carefully double-checking Antichristos's contributions to any other articles... --Steve (talk) 09:05, 19 January 2011 (UTC)

At least it looks better. By the way, something similar might be happening in article Action at a distance (physics) (edit | talk | history | protect | delete | links | watch | logs | views). It contained (or still contains) a copy of what was added here (See Talk:Speed of gravity#Word-for-word copy of another article) - DVdm (talk) 09:34, 19 January 2011 (UTC)

Gravitational radiation is not nonsence. But the idea of its detectability is indeed nonsence. See this: The search for gravity waves (Paul Davies is one of the world's top cosmologists) - Antichristos (talk) 10:04, 19 January 2011 (UTC)

I've removed the second paragraph, as being unnecessarily confusing and constituting original research (I also think that it is misleading and irrelevant to the article, since Antichristos seems to confuse detecting "classical" gravity waves with detecting individual gravitons, e.g. misunderstanding Davies' point). In the course of this it occurred to me that the last section of the article, on the speed of of gravity in general relativity, needs some attention too, preferably from someone who knows more about it than I do (I am a mathematical condensed matter physics type). Rafaelgr (talk) 10:44, 19 January 2011 (UTC)

If the average Compton wavelength of the gravitons is 1 billion light years, it does not matter whether you detect a single graviton or a billion of gravitons—in both cases, the signal will arrive instantaneously. Antichristos (talk) 11:28, 19 January 2011 (UTC)

1) Wavelength has nothing to do with propagation speed.

2) Even if the average wavelength of gravitons was 1 billion lightyears (which seems to be a novel conclusion of the Antichristos) you would still be able to detect gravitational waves of shorter wavelengths.

The Compton wavelength of any quantum, be it a proton, an electron, a photon or a graviton,^[1] is expressed as λ = hc/E and depends only on the quantum's energy (E). The universe's average photon is bluish-green,^[2] which means that its energy (E = fh) is about 7×10¹⁴ h,^[3] while its Compton wavelength is on the order of 10⁻¹⁵ light-seconds. Since the graviton is, on average, 10⁴⁰ times weaker than the photon,^[4] the Compton wavelength of the average graviton is 10⁴⁰ times larger than the Compton wavelength of the average photon. Thus, the Compton wavelength (the radius of nonlocality) of the average graviton is about 10²⁵ light-seconds, whereas the radius of the observable universe is only about 4.32×10¹⁷ light-seconds (13.7×10⁹ light years). Since the Compton wavelength of the average graviton is about 2×10⁷ times larger than the radius of the visible universe, any claims of having detected gravitational radiation or measured the "speed of gravity" are false.^[5][6]

The Compton Wavelength of the "average graviton" is irrelevant as long as there are enough higher-energy gravitons around. If we accepted your argument, we'd also have to conclude that gamma ray telescopes are impossible because the average photon is blue-green. Rafaelgr (talk) 13:19, 19 January 2011 (UTC)

In relativistic quantum theory, a system cannot be localized to a precision better than its Compton wavelength,^[7] expressed as λ = hc/E = c/f.

At f = 1 Hz, a quantum's energy (E = fh) is equal to h (the breakeven point between wave-likeness and particle-likeness), while the quantum's Compton wavelength (the radius of nonlocality, instantaneous propagation) is 1 light-second (300 thousand kilometres). According to the theory of relativity, superluminal propagation is propagation into the past. Therefore:

• A relativistic wave, whose frequency is above 1 Hz, begins its second period in the future; the third period, still further in the future, and so on. Such a wave is an electromagnetic wave; in its quantum—the photon—the particle-like magnetic phase dominates over the wave-like electric phase.
• A relativistic wave, whose frequency is below 1 Hz, begins its second period in the past; the third period, still further in the past, and so on.^[8] Such a wave is a gravitoelectromagnetic wave; in its quantum—the graviton—the wave-like electric phase dominates over the particle-like magnetic phase.^[9]

Conclusion:

1. Gravitoelectromagnetic waves, whose frequencies are below 1 Hz, are undetectable.^[10][11]
2. Gravitoelectromagnetic waves, whose frequencies are above 1 Hz, do not exist. - Antichristos (talk) 13:35, 19 January 2011 (UTC)

This argument is (a) unclear and (b) apparently unrelated to your previous argument. I would ask where it is spelled out in more detail, except that it also does not address my main contention, which has consistently been that your main edits are WP:OR. Are you familiar with the Wikipedia policy on original research?Rafaelgr (talk) 13:43, 19 January 2011 (UTC)

When the average Compton wavelength of the gravitons is 300 thousand kilometres, it does not matter whether one detects the velocity of a single graviton or the group velocity of a myriad of gravitons—in both cases, the signal will arrive to both arms of the interferometer simultaneously. - Antichristos (talk) 14:08, 19 January 2011 (UTC)

The current version is full of synthesis. I'm reverting to the vastly superior version of August.TimothyRias (talk) 12:54, 19 January 2011 (UTC)

Note: user:Antichristos has broken WP:3RR by reverting me again. I've restored my revert. (Which places me at 3 reverts, so I'm done for today, could somebody else watch the situation?TimothyRias (talk) 13:29, 19 January 2011 (UTC)

Afaics the last paragraph is definitely severely wp:overlinked, and I suspect that the closing words of the last paragraph ("not even false") are inappropriate as in wp:synt. DVdm (talk) 10:57, 19 January 2011 (UTC)

OK, I will amend it. Antichristos (talk) 11:05, 19 January 2011 (UTC)

${\displaystyle \lambda ={c \over \nu }\,}$

But the formula for the Compton wavelength is the same: ${\displaystyle \lambda ={c \over \nu }\,}$. See for yourself: Compton_length#Relationship_between_the_reduced_and_non-reduced_Compton_wavelength So, what is the difference? (LOL. Are you really so clueless?) According to you, the wavelength for a close binary star would be "shorter than a light-year." It means that the frequency of such a field would be much lower than 1 Hz. But the energy of a quantum (E = fh) cannot be lower than h, which is measured as energy per second. A field, whose f is less than 1 Hz, is not quantized, because its quantum's energy per second would be less than h. Such a field is a purely wave-like nonlocal entity known as the quantum gravitational potential,^[12] the quantum potential,^[13] or the wavefunction. Since it is nonlocal, it does not even need to propagate. So, what speed are you going to measure? LOL. - 91.122.1.73 (talk) 07:49, 21 January 2011 (UTC)

You should not talk about cluelessness.

The frequency ν in my formula is the reciprocal of the orbital period (less than one year for a close binary star) since it is the relative positions of the stars which determines the phase of the wave. (The frequency might have to be doubled for the quadrupole moment of gravitons as opposed to the dipole moment of photons.) Multiplying that period by the speed of light gives a distance less than one light-year. The closer two black holes or neutron stars are to each other the stronger the signal would be, so it is the close binaries which would be the main source of radiation which we might hope to detect someday. Quantum mechanics does not invalidate this kind of classical reasoning. Indeed in such cases, the fact that a classical gravity wave may be composed of gravitons can safely be ignored. JRSpriggs (talk) 06:54, 22 January 2011 (UTC)

The concept of a radiation, whose frequency is less than 1 Hz, defies the main tenet of quantum mechanics—the Planck postulate—according to which, a quantum's energy per second cannot be less than the Planck constant.

A field, whose f is less than 1 Hz, is not quantized, because its quantum's energy per second (E = hf) would be less than h (which too is measured as energy per second). Such a field is a purely wave-like nonlocal entity known as the gravitoelectric field,^[14][15][16] the quantum gravitational potential,^[17] the quantum potential,^[18] or the wavefunction:

The vacuum is really an expression of the continuous or noncountable nature of mass-energy (‘mass’, as the source of gravity). Continuity, as we will see, automatically makes mass-energy unidimensional and unipolar. <...> It is also responsible for quantum mechanical nonlocality and the instantaneous transmission of the static gravitational force—though not the acceleration-dependent inertial or GTR component, or the inertial reaction force that we actually measure in systems with localised mass (and with which gravity is often confused).

—Rowlands, Peter ♦ The Nilpotent Dirac Equation and its Applications in Particle Physics p. 10

• Any field, whose frequency is below 1 Hz, is a gravitoelectric field.^[19]
• Any field, whose frequency is above 1 Hz, is an electromagnetic field.^[20]

Thus, a hypothetical binary, making more than 1 revolution per second, would emit low-frequency electromagnetic radiation, also known as gravitoelectromagnetic radiation.

One final thought, Spriggs. In the Revision History, your reply is tagged as "ignore quantum mechanics," despite the fact that we are talking about gravitomagnetism. This is very telling. - 95.55.112.204 (talk) 11:02, 22 January 2011 (UTC)

Note. An internal search reveals that we now have 5 articles with recently duplicated content: "In relativistic quantum theory, a system cannot be localized..."

1. Article Gravitational wave (edit | talk | history | protect | delete | links | watch | logs | views) (see this string of edits )
2. Article Speed of gravity (edit | talk | history | protect | delete | links | watch | logs | views)
3. Article Action at a distance (physics) (edit | talk | history | protect | delete | links | watch | logs | views)
4. Article Negentropy (edit | talk | history | protect | delete | links | watch | logs | views)
5. Article Nonlocality (edit | talk | history | protect | delete | links | watch | logs | views)

All content was added by user Antichristos (talk · contribs). Is this appropriate? DVdm (talk) 14:28, 19 January 2011 (UTC)

For obvious reasons—see edit summary— I have reverted this most recent string of edits on Speed of gravity and left a third level warning on user talk page. DVdm (talk) 18:36, 19 January 2011 (UTC)

After this edit was reverted once more, I have opened an edit warring report here. DVdm (talk) 20:14, 19 January 2011 (UTC)

Antichristos (talk · contribs) says: At f = 1 Hz, a quantum's energy (E = fh) is equal to h (the breakeven point between wave-likeness and particle-likeness). Right there he's into complete balderdash, as it predicts that the point where particle and wave characteristics predominate, depends on what length of time we have chosen for our "second." He says it's one cycle per second. Why not one cycle per minute? In any case 100 cycle per second radiowaves really do not have much particle-like character. Antichristos is obviously a perveyor of crank physics. I urge treatment of his contributions as such. SBHarris 23:22, 19 January 2011 (UTC)

Antichristos is absolutely right. The energy of a quantum (E = fh) cannot be lower than h, which is measured as energy per second. A field, whose f is less than 1 Hz, is not quantized, because its quantum's energy per second would be less than h. Such a field is a purely wave-like nonlocal entity known as the quantum gravitational potential,^[21] the quantum potential,^[22] or the wavefunction. - 91.122.1.73 (talk) 07:39, 21 January 2011 (UTC)

Hey-- Antichristos doesn't even appear to know that h isn't in units of energy, but rather action (E*t or p*x). Saying that the energy of a quantum cannot be lower than h, is nonsense on the face of it. E can even be lower than hf in bound systems, as in the zero point energy of vibration, which is hf/2. In unbound systems, there are no quantum restrictions, and the energy of free particles can be anything you like-- as little or as large as you like, and without any quantum restrictions. In bound systems these come from E*t restrictions (measurement time is limited) or p*x restrictions (confinement length x is limited). Not from h. SBHarris 07:34, 22 January 2011 (UTC)

The energy of a quantum (E = fh) is the energy per second. Also, bound systems are completely irrelevant here—the talk is about gravitational radiation. You are a waste of Time. - 95.55.112.204 (talk) 10:47, 22 January 2011 (UTC)

Don't call me a waste of time when you screw up your simple units. Ef and h have units of energy TIMES time = energy-sec, not energy/sec. There is no "PER". Energy PER second is a unit of power. Planck's constant does not have units of power-- again it has units of action. How do you expect to be taken seriously when you cannot even come to grips with freshman physics 101? SBHarris 16:37, 22 January 2011 (UTC)

In the English language, per means "for each; for every," but not "divided by" or "multiplied by." Accordingly, the Planck constant is expressed in joules per second or ergs per second (i.e., as energy per second):

• The Structure and Properties of Matter
• Astronomy: a textbook
• Illuminating engineering
• A comprehensive treatise on inorganic and theoretical chemistry
• Foundations of short wave therapy
• Molecular radiations
• Atomic Medicine
• Philips Technical Review

Restricting the use of per to the meaning "divided by" is a relatively recent recommendation of the International System of Units (SI): "In both English and in French, however, when the name of a derived unit is formed from the names of individual units by multiplication, then either a space or a hyphen is used to separate the names of the individual units: pascal second, or pascal-second." This rule is artificially created, but since all school textbooks have adopted it, it should be followed. — 91.122.87.244 (talk) 19:09, 22 January 2011 (UTC)

Antichristos is on a 72 hr block. Doubtless he'll be back. -- cheers, Michael C. Price ^talk 15:00, 20 January 2011 (UTC)

There are more articles with problems due to edits by Antichristos: One-electron universe does not even mention its subject any more. -- Crowsnest (talk) 15:30, 20 January 2011 (UTC)

How many ips did they edit under as well? I'm pretty sure some ip edits to those articles were by Antichristos too. It would make it easier to figure out what to look at and very probably revert. Dmcq (talk) 15:46, 20 January 2011 (UTC)

Note that everything written by IP 89.110.4.94 (talk · contribs) in One-electron universe, by 89.110.20.164 (talk · contribs) in Speed of gravity, and by 89.110.9.221 (talk · contribs) in Action at a distance (physics), and no doubt many more IPs elsewhere, was written by the same author before they signed up for a user name. In this comment Antichristos was referring to himself in the third person ("its author"). DVdm (talk) 15:49, 20 January 2011 (UTC)

It looked like Thesis, antithesis, synthesis was original research so I've reverted it to a much earlier version.--Physics is all gnomes (talk) 16:42, 20 January 2011 (UTC)

Antichristos just made an not-logged edit as 89.110.14.26 (talk · contribs) and removed part of Action at a distance (physics). Technically, this is wp:block evasion. Can anyone have a look at whether this was indeed "his" content and whether it should be removed? DVdm (talk) 19:12, 20 January 2011 (UTC)

The IP edit does appear to be in the style of Antichristos. The IP range is too large to block (it's a /18). I'm thinking that Antichristos's current block should be extended to a month, and all the articles named above should be semiprotected. Anyone who has knowledge about these topics should consider reverting his edits, I believe. EdJohnston (talk) 19:30, 20 January 2011 (UTC)

I have left short messages on both talk pages. I think that a large part of the edits have already been reverted, including perhaps (?) the part he just removed—see my previous cmt. DVdm (talk) 19:40, 20 January 2011 (UTC)

It may be Antichristos is a sock of indef blocked Systemizer (talk): They have similar interests (given the small number of their contributions). After the indef blocking of Systemizer and before Antichristos appeared the same IP-range as mentioned by EdJohnston was active on these pages. -- Crowsnest (talk) 22:22, 20 January 2011 (UTC)

I'll add a request for a sockpuppet investigation to Wikipedia:Sockpuppet investigations/Systemizer, I'm pretty sure they're all the same person. Dmcq (talk) 22:47, 20 January 2011 (UTC)