Could High Energy Virtual Particles Destroy a Starship?

In summary: We're implicitly assuming that it's a given, and that's not really fair. There are certain situations in which energy conservation may not be valid, and that's what virtual particles are for- to help us visualize those situations.
  • #71
Polyrhythmic said:
Sorry, maybe I was misinterpreting you! I thought that you interpreted the text in such a way that virtual particles actually were physical objects, sorry!

No worries ;-)


Polyrhythmic said:
Then why are so many people here claiming that virtual particles are the answer?

Well, maybe some are. I think others like myself are saying they're currently the only useful answer, or way of talking about these things, even if a potentially incorrect way at that.
 
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  • #72
Polyrhythmic said:
My point is that a physical theory can only answer "why"-questions to a certain degree. At some point, you have to assume fundamental entities within such a theory. In our case the fundamental aspect would be the influence of fields on charges. One could always ask further "why"-questions which the theory can't answer.

Agreed with that. I think the whole "clear-cut mechanism behind forces w/o virtual particles" is a "why" question that QFT seems somewhat ill-equipped to answer.

Regardless, you do see a trend for folks not requiring physical theories to actually describe physical reality. The old "shut up and calculate" mantra in QM is one example.
 
  • #73
dm4b said:
Well, maybe some are. I think others like myself are saying they're currently the only useful answer, or way of talking about these things, even if a potentially incorrect way at that.

I understand that point, but I also think that people should be more understanding when people who have actually studied QFT and know details about the story tell them that they a wrong in certain aspects. It's like people are stuck with a false concept despite all the evidence against it. I personally believe that it is better to have no explanation for something than employ a wrong explanation. It leads to too many misconceptions and misunderstandings.
 
  • #74
dm4b said:
Regardless, you do see a trend for folks not requiring physical theories to actually describe physical reality. The old "shut up and calculate" mantra in QM is one example.

Well, this basically goes down to the question whether something like an absolute reality exists, or not. All we can rely on is experimental data, and theories can only be judged by whether they fit the data or not. "Shut up and calculate" might seem like a narrow-minded approach, but it makes sense in most cases.
 
  • #75
Polyrhythmic said:
I understand that point, but I also think that people should be more understanding when people who have actually studied QFT and know details about the story tell them that they a wrong in certain aspects. It's like people are stuck with a false concept despite all the evidence against it. I personally believe that it is better to have no explanation for something than employ a wrong explanation. It leads to too many misconceptions and misunderstandings.

I think part of the problem is there is not a clear message coming from the professionals on the issue. You can find publications on arxIv, and such, that talk about VPs as if they are "real", you got Lisa Randall talking about them on the Science channel as if they are real, and you got that one thread from on here a ways back where that one dude emailed many big name physicists on the reality of virtual particles, on got back a whole host of answers with more disagreement between them than agreement.

And, like, who is Joe Schmoe going to believe? Me, you, or Lisa Randall?

I also think the Joe Schmoes of the world are smart enough to sense, that even the professionals don't totally know what is going on, even if they don't technically know the details, as to why.

I think it all falls back to that issue that there are really no other clear-cut, simple and concise ways to communicate what is physically going on. So, when the "scientists" try to convey results to the general public, they can fall into the same trap.

It's just one big vicious cycle, lol
 
  • #76
dm4b said:
I think part of the problem is there is not a clear message coming from the professionals on the issue. You can find publications on arxIv, and such, that talk about VPs as if they are "real", you got Lisa Randall talking about them on the Science channel as if they are real, and you got that one thread from on here a ways back where that one dude emailed many big name physicists on the reality of virtual particles, on got back a whole host of answers with more disagreement between them than agreement.

And, like, who is Joe Schmoe going to believe? Me, you, or Lisa Randall?

I also think the Joe Schmoes of the world are smart enough to sense, that even the professionals don't totally know what is going on, even if they don't technically know the details, as to why.

I think it all falls back to that issue that there are really no other clear-cut, simple and concise ways to communicate what is physically going on. So, when the "scientists" try to convey results to the general public, they can fall into the same trap.

It's just one big vicious cycle, lol

I agree. When you break down something complex so that the general public can understand it, there is always the danger of losing or mixing up important information, so that the outcome is something completely different than what you originally wanted to convey. One has to be careful!
 
  • #77
Polyrhythmic said:

Arnold Neumaier thinks that the Coulomb field is fundamental and not quantized. IMHO, he is very wrong. But it seems to have become un-necessarily contraversial but you have to take that stance if you don't think virtual particles are real. I don't think it was this way 20 years ago. But all this posturing is silly for the simple reason that you can't properly describe muon decay without a real "off mass shell" W boson being involved. That really should be the end of the discussion about this. "Virtual" is really a bad name as they really aren't virtual. They have all the properties of "real" particles except that they are "off mass shell".

Fred
moderator sci.physics.foundations
 
  • #78
Part of the problem is when professional physicists use terms such a popping in and out of existence, extra undescribable dimensions, etc. The public loses faith in the research. I know when I first started hearing those terms used my first gut reaction was one of scorn. This scorn was so strong that it took me another year or two to even consider any validity in the whole field of quantum mechanics in general.
After finally accepting that quantum mechanics does have very accurate predictions and only after realizing that did I finally look deeper than that initial reaction.
This isn't an uncommon problem talk to any non physicist about these concepts and many would think your crazy lol.
 
  • #79
FrediFizzx said:
Arnold Neumaier thinks that the Coulomb field is fundamental and not quantized. IMHO, he is very wrong.

By stating this, you are stating that QED is "wrong".

But all this posturing is silly for the simple reason that you can't properly describe muon decay without a real "off mass shell" W boson being involved.

You keep claiming this, but you have nowhere shown something to back you up. What you say is simply not true.
 
  • #80
Mordred said:
Part of the problem is when professional physicists use terms such a popping in and out of existence, extra undescribable dimensions, etc. The public loses faith in the research. I know when I first started hearing those terms used my first gut reaction was one of scorn. This scorn was so strong that it took me another year or two to even consider any validity in the whole field of quantum mechanics in general.
After finally accepting that quantum mechanics does have very accurate predictions and only after realizing that did I finally look deeper than that initial reaction.
This isn't an uncommon problem talk to any non physicist about these concepts and many would think your crazy lol.

This is why one should stick to facts, not to intuition.
 
  • #81
Polyrhythmic said:
By stating this, you are stating that QED is "wrong".

You keep claiming this, but you have nowhere shown something to back you up. What you are saying is simply not true.

How would that make QED wrong? There are many examples of quantization of the Coulomb Field in textbooks.

I have given a very simple description of muon decay. Here it is again,

Standard Model description of muon^- decay; muon^- decays to a muon neutrino and a real "off mass shell" W^- boson. The W boson then decays to an electron and an electron anti-neutrino. Of course it is difficult to have discussion about that since there is no other way to describe the decay than by a virtual W boson.

Fred
 
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  • #82
dm4b said:
Really, when you think about it even the virtual particle description is not a very "useful" description, or heruistic, for describing and explaining how forces work. It also seems rather magical. In addition, when you realize the perturbation series is an infinite serires and therefore any process involves an infinite number of virtual paritcles, it gets even more magical.

I personally think all this shows we still have a lot to learn, regardless of how much we think we know.

Lots of folks feel that all the divergences and infinities within QFT indicate an underlying problem with the theory. I can't help but wonder if somehow that was fixed, would we get a new view of how forces "work", which does not include virtual particles.

let say we believe that virtuals are real and "physical" . So what is charge anyway, and what is mass, it is equivelant to energy, oh , what is energy. and what is a photon made of, and how it leaves an electron and how an electron jumps to another level after that. What is a particle ,is it field (of what) or is it litte ball (of what). So can we say we know something but we don't know where and how it became! What is "physical" about these little things and gostly forces which we have nothing in the macroscopic world to compare to. These are models , just models . until a full theory is in hand that explains the why of all these things. The theories remain just approximate models.
 
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  • #83
FrediFizzx said:
How would that make QED wrong? There are many examples of quantization of the Coulomb Field in textbooks.

I think I got you wrong, do you mean the quantization of the vector potential [tex]A_{\mu}?[/tex] Anyways.

Standard Model description of muon^- decay; muon^- decays to a muon neutrino and a real "off mass shell" W^- boson. The W boson then decays to an electron and an electron anti-neutrino. Of course it is difficult to have discussion about that since there is no other way to describe the decay than by a virtual W boson.

What you describe here is one distinct Feynman diagram. It is no picture of physical reality...
 
  • #84
Yes, quantization in the Lorentz gauge of [tex]A_{\mu}.[/tex]

Please get Feynman diagrams out of your head. Now, can you please describe muon decay any other way from the way I have described it? You can't. There has to be a W boson involved in the description or quantum numbers will not add up correctly.
 
  • #85
Wow, this thread has an angels-on-pinheads quality to it, doesn't it? A lot of people tossing around terms they aren't entirely comfortable with, trying to describe a reality that is stubbornly complicated.

Ken G said:
All I would personally like to know is whether there is a way to understand electrostatic interaction (not scattering) at the quantum level without the virtual photon concept being useful.

Surely you know this already, don't you? There are answers at every level. At the simplest level, we have the Schrodinger equation in 3 dimensions. How do we describe the interaction of the negative electron with the positive nucleus? Simple. We insert the Coulomb potential into the equation, V = -K/r. Then we solve for the stationary eigenstates, which gives us the familiar spherical harmonics times radial eigenfunctions (exponential times Laguerre polynomials). We also have to make an outer product with the electron spin state, of course. This gives a wonderfully accurate description of hydrogenic (i.e. single-electron) atoms. [My best reference on this is an obscure book by Sol Wieder, The Foundations of Quantum Theory, but this is really basic stuff.] The same machinery would apply to the electrostatic interaction between any two slowly-moving charged particles -- however, if there are no bound states (e.g. electron-electron scattering) then you get a different set of eigenfunctions.

If we want to understand the dynamic interaction of an charged particle with an electromagnetic field, then we have to write the electromagnetic vector potential as an operator. The operator is a sum of creation and annihilation operators, with appropriate doo-dads in front. Then we make a canonical substitution in the Schrodinger equation p -> p - e*A/c. You also have to add a term for the spin-magnetic interaction. [My best resource is Sakurai, Advanced Quantum Mechanics]

Beyond that, we have learned a lot from perturbation theory. And that's where virtual photons come in...
 
  • #86
Re: High energy virtual particles

--------------------------------------------------------------------------------

Originally Posted by Mordred
Part of the problem is when professional physicists use terms such a popping in and out of existence, extra undescribable dimensions, etc. The public loses faith in the research. I know when I first started hearing those terms used my first gut reaction was one of scorn. This scorn was so strong that it took me another year or two to even consider any validity in the whole field of quantum mechanics in general.
After finally accepting that quantum mechanics does have very accurate predictions and only after realizing that did I finally look deeper than that initial reaction.
This isn't an uncommon problem talk to any non physicist about these concepts and many would think your crazy lol.



This is why one should stick to facts, not to intuition.



I fully agree Polyrhythmic one should stick to facts not fiction, sounds easy doesn't it until you account to all the fictionous articles commonly published on the internet, broadcasted by news articles etc. Even highly reputable magazines doesn't always publish articles based on facts alone. When you don't work everyday with dealing with these facts, or in a different profession seperating fact from fiction is rather tricky lol.

Makes me glad my job is merely making robots and plant machinery simply work to within an acceptable degree of accuracy.
 
  • #87
Mordred said:
Part of the problem is when professional physicists use terms such a popping in and out of existence, extra undescribable dimensions, etc. The public loses faith in the research.

Speak for yourself. The weirder physics gets the more I like it, lol.
 
  • #88
I have to agree with that in a way it does keep things interesting lol
 
  • #89
Ken G said:
Can you describe for me an experiment that detects a real gluon? That would make the discussion more concrete. Also, what is a quantized description of the interaction between two stationary charges that admits to no reasonable interpretation involving virtual photons?

A better question is whether any experiment ever really detects "real" particles. Here is an interesting quote from David Griffiths, Introduction to Elementary Particles:

Actually, the physical distinction between real and virtual particles is not quite as sharp as I have implied. If a photon is emitted on Alpha Centauri, and absorbed in your eye, it is technically a virtual photon, I suppose. However, in general, the farther a virtual particle is from its mass shell, the shorter it lives, so a photon from a distant star would have to be extremely close to its "correct" mass; it would have to be very close to "real." As a calculational matter, you would get essentially the same answer if you treated the process as two separate events (emission of a real photon by star, followed by absorption of a real photon by eye). You might say that a real particle is a virtual particle which lasts long enough that we don't care to inquire how is was produced, or how it is eventually absorbed.

When we glance at the sun, do we see "real" photons? Griffiths suggests: not exactly, but they are darn close.

The question is even trickier with uncharged particles, because we humans lack direct sensors for the weak and strong nuclear forces. Do we ever detect "real" neutrinos? Every now and then the photomultiplier tubes at Kamiokande go crazy, and the pattern of Cerenkov radiation indicates a solar neutrino has struck an atom in the detector. But those neutrinos are ostensibly "virtual" in exactly the sense Griffiths describes -- but darn close to "real".

So far the jet experiments are the closest we have to detecting "real" gluons; the jet gluons are close enough to being on-shell that they form collimated jets when they decay. But, like the neutrinos and photons, they are really only "almost real".

Given all the other approximations and contortions associated with quantum field theory, I wouldn't get too wrapped around the pole thinking that "real" particles (in the QFT sense) have more than a passing correspondence to "real" particles (in the everyday sense). In QFT, when we say a particle is "real", we simply mean that it is represented by an external line in a collection of Feynman diagrams. The patter that connects the collection of Feynman diagrams to an experimental result is just an imperfect way to express the relation of mathematics to reality.
 
  • #90
FrediFizzx said:
Well, I would like to see how *anyone* here disputing that virtual particles aren't real would model decay of charged pions and muons without virtual W bosons. This is the Standard Model of particle physics, folks. Well established even by the LHC now.

You are using "real" in a sense that is not used in quantum field theory.

In QFT, internal lines in Feynman diagrams represent "virtual" particles. The external lines in a collection of Feynman diagrams represent "real" particles. So "real" particles are not "virtual", at least in the sense that QFT uses the words.

If all you are trying to say is that there is such a thing as a W boson, no one is disputing that. If you are trying to say that the internal line (that represents a W- in muon decay) is an external line also, then no, that is not true.

However, I sense that you have a misunderstanding of the meaning of the tree-level muon-decay-via-W diagram. Individual Feynman diagrams do not correspond to physical processes. Only the sum of the infinite number of Feynman diagrams that satisfy the boundary conditions (i.e. momenta on the external lines) represents a physical process.
 
  • #91
OK, a lot of good points are being made. A particularly important one would seem to be that electric forces are only mediated by virtual photons in some gauges-- this was interpreted above as indications they are "not real." There are several problems with using this to dismiss taking virtual particles seriously as ontological constructs:
1) virtual particles are not claimed to be real, they are claimed to be virtual. This means they seek a new ontological status that normal standards of "realness" cannot be applied to. That seems obvious, but is getting overlooked.
2) virtual particles that mediate forces like the one corresponding to the Coulomb potential are gauge bosons, so it is perhaps not surprising they are not present in all gauges. The purpose of a gauge is not to make a claim on reality, it is to make a calculation simpler. It might well be argued the same can be said about physics in its entirety (echoing qsa above). So although it is useful to establish that virtual photons can be done away with in certain gauges, the question that remains is whether or not we gain access to certain forms of computational convenience by choosing a gauge that supports such gauge boson activity, at the conceptual level. Is anything in physics theory not at the conceptual level, after all?

So anyway, I'm not advocating for the reality of virtual particles, we shouldn't even call them virtual were that the attitude. I'm merely questioning whether or not it really makes consistent logical sense to imagine that physics supports a clear line between what is real and what is just a mathematical trick in some theory. We use any foothold we can get when trying to interpret and understand reality, and we cannot be burdened by the need to make the case that any ontological entity we invoke is "actually real."
 
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  • #92
bbbeard said:
When we glance at the sun, do we see "real" photons? Griffiths suggests: not exactly, but they are darn close.
Yes, I think I am very much on Griffiths' page here, that's a nice quote. The point is, when we do physics, we make all kinds of choices about what we care about and what we don't. Those choices will have as much an influence on what we regard as real as what is "actually real." In particular, the former has a clear-cut meaning, and the latter does not.
So far the jet experiments are the closest we have to detecting "real" gluons; the jet gluons are close enough to being on-shell that they form collimated jets when they decay. But, like the neutrinos and photons, they are really only "almost real".
I'd say you've really set the discussion on its ear-- we were debating whether there is actually any such thing as virtual particles, and you are making a strong case that we should really be asking whether there is actually any such thing as real particles. Coup de grace.
The patter that connects the collection of Feynman diagrams to an experimental result is just an imperfect way to express the relation of mathematics to reality.
Spoken like a true empiricist. I think it's times like this that the gap between empiricist views and rationalist views really creates communication barriers, it's just as well that physics proceeds without reaching resolution of this kind of issue.
 
  • #93
Ken G said:
Spoken like a true empiricist. I think it's times like this that the gap between empiricist views and rationalist views really creates communication barriers, it's just as well that physics proceeds without reaching resolution of this kind of issue.

LOL I had a math professor once state that mathematics is the only universal lanquage, that may be true but it certainly has many dialects and interpretations.

I like this site as an excellent and simple explanation of virtual particles for the novice
It doesn't swamp one with formulas or complex lanquage. I personally think that the term "intermediate particle " or something similar would have led to greater overall acceptance than the usage of the word virtual. Granted this site doesn't present the full picture but it often is useful in explaining the concept to the novice.

http://www2.slac.stanford.edu/vvc/theory/virtual.html
http://www2.slac.stanford.edu/vvc/theory/quantum.html

edit: I also found this article was informative and useful in the past

http://math.ucr.edu/home/baez/physics/Quantum/virtual_particles.html

I posted these to aid understanding to the beginners that frequent this site tidbits like tthese have proven useful in the past so I gathered a collection of em currently around 4 giga bytes worth lol
 
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  • #94
Polyrhythmic said:
Even though perturbative quantum field theory has proven to be extremely successful, the lack of a proper non-perturbative theory is kind of unsatisfying.

You should look into what's going on in lattice gauge theory. For example, check out http://pdg.lbl.gov/2011/reviews/rpp2011-rev-ckm-matrix.pdf" . Scroll through and see how lattice gauge theory is used to produce estimates of important physical quantities.

While there is no doubt that lattice methods are not as well-developed as perturbative QFT, they don't suffer the same limitations in the strong-coupling regime...
 
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  • #95
Ken G said:
I'd say you've really set the discussion on its ear-- we were debating whether there is actually any such thing as virtual particles, and you are making a strong case that we should really be asking whether there is actually any such thing as real particles. Coup de grace.

It seems to me there are a number of situations like this in physics. Are you familiar with the "thermodynamic limit"? The theory of phase transitions in thermodynamics, it turns out, really only works for infinite systems, or more precisely, in that limit. So we can reasonably ask whether the water boiling on the stove is "really boiling" or just "virtually boiling"...
 
  • #96
bbbreard do you happen to know of a good site that teaches the Cabibbo-Kobayashi-Maskawa (CKM) matrix? If so I would be highly interested I use standard matrix calculations regularly however the standard 3 degrees of motion matrixes used in engineering which are limitted in that they do not include the time dimension if you happen to know of a means to describe a 4-d matrix I would be highly interested in how its derived and used. I would also be interested in virtual boiling and the phase transitions in thermodynamics my first impulse is the transitory point from one state to another where additional energy is needed to change from solid to liquid etc but these are new terms to me so am probably wrong on that score lol.
 
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  • #97
Mordred said:
bbbreard do you happen to know of a good site that teaches the Cabibbo-Kobayashi-Maskawa (CKM) matrix? If so I would be highly interested I use standard matrix calculations regularly however the standard 3 degrees of motion matrixes used in engineering which are limitted in that they do not include the time dimension if you happen to know of a means to describe a 4-d matrix I would be highly interested in how its derived and used. I would also be interested in virtual boiling and the phase transitions in thermodynamics my first impulse is the transitory point from one state to another where additional energy is needed to change from solid to liquid etc but these are new terms to me so am probably wrong on that score lol.

The CKM matrix is a 3x3 matrix that relates the strong (i.e. QCD) eigenstates of the down, strange, and bottom quarks to the weak eigenstates of the same quarks.

One of the little-publicized quirks of the Standard Model is that the down particle in QCD is slightly different from the down particle in the weak interactions. Ditto strange and bottom. The free parameters in the CKM matrix (three Cabibbo angles and a phase factor) are some of the plethora of free parameters in the Standard Model.

If you want to learn more, just google "CKM matrix"... ;-)
 
  • #98
CKM matrix? This has gone way far afield of the original question.
 

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