Topological Solitons of Ellipsoid Field - Particle Menagerie Correspondence by Jarek Duda

Ted,

What is nice about topological solitons is that you can get intuitive understanding without going into sophisticated mathematics - here you have Wikipedia article with nice animation of solition-antisoliton pair creation or annihilation. The field prefers to be in -1 or +1, but sometimes external conditions enforce it to charge these energy minimums - soliton is the least energetic way to do it. This minimal energy is its rest mass. Such topological constrain can be released while annihilation - releasing energy in form of non-topological waves: photons. If you want to understand more dimensional solitons, you can start with this simple demonstration.

Thanks,

Jarek

Jarek,

Your essay will take quite a bit of time for me to digest. After viewing your ease with vector fields, I would like your comments on stress tensors (which may help me relate my own essay to solitons). If I were to model particles as instead holes traveling within a medium, would it be correct to model the stress tensor for the hole [math]\kappa T_{\mu\nu}[/math] or for the remaining medium [math]=\Omega g_{\mu\nu}-\kappa T^{res}_{\mu\nu}[/math] (where the "res" is for the residual medium and Omega is the non-stressed medium in the immediate neighborhood)?

Regards,

Jeff Baugher

Dear Jarek Duda,

I found your essay quite interesting. I too believe that topological soliton-like structures are the best approach to particle physics, and I agree that focus on a de Broglie 'clock' is appropriate, and there is a need to explain Zitterbewegung.

I found your figure 5 on page 6 also interesting and will give that more thought. Of most importance to me was your mention of gravito-magnetism on your last page. With this in mind, I invite you to read my essay, The Nature of the Wave Function, which does not deal with particle creation but with the quantum mechanics of existing particles.

Good luck in the contest.

Edwin Eugene Klingman

Jarek,

I saw the illustrations and did a search for Möbius but failed to put in the umlaut.

The photonics folks use the term Orbital Angular Momentum (OAM) to describe optical frequency EM waves with a helical wavefront. The wavefront is no different than circular polarization which has been utilized many decades for radio communications. I am aware that optical frequency beams with OAM are used as optical tweezers.

Please note that the helical EM (HEM) structure of the one EM field provides the unique chirality feature that allows two fields of the same type at 180° to couple. Next to chirality, the angular phase position characteristics are very significant. I quote from my paper "Whether an electric or magnetic field, the angular phase position (APP) of the EM field vectors will be fixed relative to the HEM source orientation. In comparison to the simple pull characteristic of gravity, the APP is a HEM field trait that will cause a more complex interaction between objects with different APPs."

I notice your one Möbius illustration has a double twist. A "Möbius space" requires a 720° path to achieve a 360° rotation of a plane object in the space.

Do you realize that you are presenting material as to why ionizing radiation is so destructive to biological tissue, the rotational form of the energy field allows it to efficiently couple to DNA and other helical structures within the body.

Jeff,

You can try to imagine yourself the behavior of this simple real symmetric tensor field preferring some set of different eigenvalues - its family of stable structures and their dynamics ... and compare it with known physics (please let me know if you find some essential discrepancy).

I don't think there is a simple correspondence between this real symmetric tensor field and energy-momentum tensor (much closer is stress tensor): very different values appear in them, the second is effective while the first is intended to be much more fundamental, energy density is directly written in the second while in the first you need to use potential energy for that etc.

The kinetic term in Lagrangian is probably also quite different, like -Rab Rab of prof. Faber ... but it should lead to gravitomagnetism on more effective level, which is good approximation of GRT (up to our measurement possibilities).

The question of choosing both kinetic and potential term is extremely subtle here - I would be grateful for some suggestions how to do it right - I think similarly as in the Faber's model, but include the difference between axes, making e.g. that energy density of electric field of electron, muon and taon charge are a bit different.

Thanks,

Jarek

Dear Edwin,

Thank you for your comments and interesting essay. We know that particles are localized field configurations, what is also definition of soliton and e.g. charge quantization leaves no doubt that we should use the topological ones - I don't think the question is if we should use topological solitons to mode particles, but how.

Sadly very few people search for such finally objective, local and deterministic physics from which QM would emerge on more effective level - e.g. while most of speakers in recent Congress of Emergent Quantum Mechanics was still focused on double-slit experiment (like thanks of recently weakly measured from the first page of your essay - it was the second achievement emphasized there after Couder), very few is searching for this physics below quantum description.

There are important questions how this de Broglie's clock should look like. For example are these produced waves only local (vanishing), or maybe single electron in the universe would make the quantum phase rotates everywhere ... the second option seems nonintuitive, but in Schroedinger's picture this single electron would also enforce quantum phase of the whole universe to rotate. Fortunately electron is created together with positron, which should compensate rotation caused be electron to nearly zero.

Thank you for the wishes, but I'm fully aware that solitons are not a popular subject and good luck won't change it - I'm here for a discussion rather.

As you know where to search for real understanding of particles, I wish you good luck with finding the proper one ...

Jarek

Hi Jarek

Very interesting work, I liked it very much. I must confess that I am not an expert in soliton theory though I understand the fundamentals and the virtues of solitons as an intuitive picture at the microscopic level. I have read your previous comments to other contestants and I am aware that not many physicists embrace solitons as an alternative formulation to describe the microscopic world. If you do not mind I would like to ask you some questions that I would be happy if you could give me some comments. First of all, I am curious about your opinion in relation to the attitude of theorists and I would like to ask why do you think particle physicists do not see with sympathy the notion of solitons?

On the other hand, in relation to your work, it was not clear for me how the photon is represented in the soliton language, I mean what is the topological difference between an ordinary particle-like soliton and a photon-like soliton. In this sense, I ask myself that being a soliton some sort of wave, does this imply some sore of medium or background? I mean, do they just travel through the quantum vacuum? My point is that you said that a photon-like soliton keeps the same amplitude independent of the distance. I think that at cosmological distances the vacuum may act as a dissipative/dispersive medium for the photon-like soliton and thus it will lose some energy while moving from the source to the observer. Laboratory experiments in fluids suggests that the amplitude of solitions for relatively short distances does not vary, but for astronomical distances this may not be true. Do you know any formulation that accounts for this?

I was also interested in the problem of the temperature of the solar corona which I did not understand well from your essay; I mean, how do the soliton formulation will be useful to explain this problem? I think this is one of the most important problems in physics.

At the end of your essay you said: "This simple approach is all or nothing". Do you think that the formulation of soliton theory applied to physics has some problems?

I thank you very much for your comments and I invite you to read my essay.

Israel

Hi Israel,

I think the problem with appreciating solitons is the feeling that models should be derived from e.g. the standard model, like in the most popular: Skyrme approach. The philosophy I present is just opposite: accept that modern physics has grown by building the believe in the previous assumptions and then building new ones on the top while something occurs to be wrong/missing ... I think we should instead try to start once again using the current knowledge - try to recreate everything as consequences of some extremely simple basis. Kind of similar philosophy is used in string theory, but they start with complete abstract and after a quoter of century it still doesn't lead to any better understanding, while soliton models start with the mechanism of charge quantization and the origin of mass...

About the photon, personally I see it as nontopological(massless) soltion - carrying angular momentum twist-like wave, like behind marine propeller, but this time in no viscosity medium and so can travel nearly undeformed though light years (?). However, prof. Faber believes they also have topological nature, making them more stable. They indeed require some medium - it is the electromagnetic field, which is reformulated in this approach to enforce charge quantization. This vacuum like in QM e.g. carry EM and gravtiational waves, allows for spontaneous pair creation and many other properties making it much more than just empty space.

About the coronal heating problem, I also see it as one the major ones. The help from soliton models is that they suggest existence of vacuum analogues of Abrikosov vortices - stable string-like objects related to magnetic field, carrying some energy density per length - such objects are observed as so called magnetic flux ropes, which also carry ions in stable way: their energy come from vortices on the surface caused by differential rotations and is released in the corona while reconnections which shortens them.

"This simple approach is all or nothing" was only about this exact approach to find a complete soliton model. Similar but essentially different search to do it has e.g. prof. Faber. In opposite to the standard way, they rather do not leave a lot of freedom ...

Cheers,

Jarek

Hi Jarek

Thanks for your reply.

You: "I think the problem with appreciating solitons..." I agree with this. I have promoted the replacement of particle by solitons though many physicists instead have the notion of quasi-particle, and therefore this labeling demote them to a second rank below a particle. I recognize the potentiality of solitons as a fundamental conception in physics as well as their benefit. They are well used in many branches of physics but perhaps the fact that they do require a medium to exist makes them not to be very welcome in fundamental physics.

You: They indeed require some medium - it is the electromagnetic field, which is reformulated in this approach to enforce charge quantization. This vacuum like in QM e.g. carry EM and gravtiational waves, allows for spontaneous pair creation and many other properties making it much more than just empty space.

You may be referring to the zero-point field (ZPF). According to QFT the Higgs field, the fermion fields and the guage fields are manifestations of the fundamental field, the ZPF or vacuum energy (at zero temperature). And this is my point. Photon-like solitons should move through the ZPF, but I wonder whether the ZPF, being the medium for solitons, is dissipative/dispersive like any classical medium. This would be relevant at cosmological distances. And if this is true then the soliton-like photon must lose a slight amount of energy as it moves through the ZPF until it is completely reabsorbed by it. So I am wondering the implications of the soliton-like formulation of the photon that accounts for this effect since you assume that the photon is massless and it only carries energy and momentum. Do you have any idea of this or any reference I can look over?

You: ...magnetic flux ropes, which also carry ions in stable way: their energy come from vortices on the surface caused by differential rotations and is released in the corona while reconnections which shortens them.

Well, I study superconductors but here again the notion of vortices implies a medium in which persistent currents (or magnetic flux) maintain the vortices in action. As far as I can understand it seems that you are saying that there is magnetic energy stored in the inner layers of the sun and then by some mechanism it is released at the corona which causes an immense increase of temperature, is that the idea?

Cheers

Israel

Hi Israel,

Indeed the soliton approach is still seen as an exotic concept by particle physicists. They are satisfied with QFT description, but it is only a general mathematical tool to work on completely abstract entities (like algebra) - not asking what particles really are. Skyrme model is still alive for short range interaction of baryons, but its specialists emphasize that it is effective model and we cannot get below mesons by this approach. Dirac monopole topic is also alive, but they rather don't exist - prof. Faber repairs it by using dual formulation of EM, making them electric monopoles - with long-range EM interaction.

About the field, one can call it ZPF or (Lorentz-invariant!) ether, but in vacuum (far from particles) practically the only dynamics (besides gravity) is EM - we can only reformulate, complement it a bit, like by charge quantization, extending the field to where standard EM cannot be defined well like in the center of electron - giving it mass.

About the photons, I have to admit that I haven't seen satisfactory models before, while for my picture I am not ready yet to show that they completely don't dissipate - my argument is only that EM has no viscosity, so there should be no transverse transport of angular momentum, which could damage such twist-like wave.

About coronal heating problem, magnetic flux ropes are seen in photographies of the Sun, their reconnections is one of used explaining mechanisms. Their consequence is for example "bubble-like foam" on the edge of heliosphere observed by Voyager( http://www.nasa.gov/mission_pages/voyager/heliosphere-surprise.html ). What I suggest is that they are not only stream of ions, but maybe there is also a physical nearly 1D construct of magnetic flux inside: stabilized by topology and carrying additional energy per length. There is some persistent current of ions circulating around it, but I think of something more fundamental: where Re(phi)=0 and Im(phi)=0 submanifolds intersect for quantum wavefunction phi - so called vortex lines. See a paper of prof. Bialynicki-Birula about these consequences of QM, like: http://www.cft.edu.pl/~birula/publ/VortEM.pdf

Cheers,

Jarek

Hi Israel,

Yes, the discovery of Voyager is very interesting and should motivate to think about these magnetic structures, like if they could remain such complexity in standard electrodynamics. Anyway, I think the corona heating problem should bring much more attention - showing that we don't understand something looking very fundamentally: just dynamics of EM field with charges.

About aether and your essay, Lorentz invariance seems really natural assumption in field theories - I honestly don't see a need for some more preferred frame of reference.

Generally I really appreciate philosophical disputes, but there was more than a century of similar ones and they hasn't changed much ... like most of speakers on recent "Emergent Quantum Mechanics" speaking about double slit ... I think it is enough of general discussions - if we want to move toward a better understanding, we need to propose concrete alternative, concrete models ... e.g. if you agree that we should search for field configurations behind particles (soltions), try to work in this direction. Having really understood microscopic physics, astronomical should appear naturally.

Cheers,

Jarek

Hi Jarek

Thanks for your reply. The preferred system of reference (PSR) --specially at the macroscopic scales (at the microscopic one seems to lose its scientific value)-- is necessary for several reasons: for logical consistency, because if light is seen as a wave, a wave requires a medium. One must be aware that all actual media are dissipative. And since light travels trough a medium it should lose some energy at cosmological distances, this explains Hubble's law without resorting to the expansion of the universe. It also solves Olber's paradox, etc. (I explain this in my entry in a discussion with Daryl Danzen and John Merryman). And this one of the reasons I have interest in the solition representation of a photon. If you read my essay please see reference 17 there you will find that for the description of light it is necessary to have a PSR. I see the aether and the quantum vacuum as synonyms.

You: About aether and your essay, Lorentz invariance seems really natural assumption in field theories - I honestly don't see a need for some more preferred frame of reference.

I think that there is a misunderstanding here. Most people believe that Lorentz invariance per se excludes a PSR. However, it has been shown that Lorentz invariance and quantum mechanics could be derived from the assumption that the vacuum is some sort of aether of Planck plasma. From here Lorentz symmetry is a natural emergent feature with no logical contradictions. You may wish to join the philosophical discussion with Daniel Wagner in my entry in relation to PSR. As you say this problem and the slit experiments are never ending debates (though assuming the aether and considering solitons the slit experiment is very easily solved, i.e., quantum mechanics becomes very intuitive and local). So, I will move forward with the idea of solitons and the PSR. I think I have found a consistent conceptual framework to explain most of the present problems in physics, though this requires a radical change in our conception of physical phenomena.

Thanks again for your stimulating comments, I really enjoy our discussion and I hope you get some time to read my essay. I would appreciate your comments.

Cheers

Israel

Hi Israel,

The problem of photon dissipation is indeed one of the most fundamental questions of physics, but I don't see how preferring a system of reference could help here? What we need is a concrete model of how this EM soliton looks like instead. One possibility is trying to model photons as carrying a topological constrain like for massive particles - advocated by prof. Faber. It requires using a field with complex hidden degrees of freedom. I would prefer to see photons as something simpler and just being twist-like wave seems to be completely enough. Imagine such wave behind marine propeller - it dissipates only because of viscosity - not true?

Personally I don't see the necessity of never-ending debate about e.g. the double slit. Just oppositely - I think it's enough of general talk and time to get concrete. Completely satisfactory for me is picture presented by Couder's experiments (video and other sources) - particles are simultaneously corpuscles and conjugated with them waves around - caused by some internal periodic process (de Broglie's clock) - now it's time to find concrete model of these entities ("breathing" solitons).

Thank you for the discussion, I really tried to read your essay but it's just too philosophical for me. Much more gladly I would discuss looking more concrete "conceptual framework" using solitons you have mentioned ...

Cheers,

Jarek

Hi Jarek

You: The problem of photon dissipation is indeed one of the most fundamental questions of physics, but I don't see how preferring a system of reference could help here?

The motion of a photon (or better of a wave of light) has to be referred to a medium, i.e., the quantum vacuum or the zero-point field (ZPF) itself which can be considered as the PSR. Since all particles (solitons) are embedded in the ZPF they all move relative to it. The Casimir effect can be considered as a proof of the existence of the ZPF (or vacuum or aether, the name is not important).

You: What we need is a concrete model of how this EM soliton looks like instead.

I think light can be treated like a classical wave, there is no need to modify it at all but I do not know if this version is compatible with the topological formalism.

You: Personally I don't see... ... now it's time to find concrete model of these entities ("breathing" solitons).

I agree, we have to try to get a conceptual and theoretical framework where to put all this ideas in a coherent way.

You: I really tried to read your essay but it's just too philosophical for me.

I agree that it is too philosophical but one has to build not only a strong mathematical framework but also a philosophical one so both appear consistent. We have to work out the philosophical principles and with this as a basis we can work out the mathematical formalism. Commonly people work the opposite way, first, they look for a mathematical formalism, proposing fields, potential, lagrangians, etc. (e.g. string theory, loop quantum gravity, etc), and later try to find a physical interpretation to the mathematical outcome. But many theoretical physicists have realized that this heuristic procedure has not been effective for the last 30 years (physics crisis). And I believe, among other things, this one of the motives of this contest. Around these days, Vesselin Petkov (one of the contestants) and some of his collaborators are about to inaugurate the Herman Minkowski Institute. One of the aims of this institute is to recover the old way of doing physics, i.e. including the philosophical analysis for the development of the theory, you should take a look at it here. Physicists are worried why there has not been a major breakthrough for the last 80 or 90 years since the discovery of relativity and quantum mechanics.

Cheers

Israel

Dear Israel,

Ok, I think I see your point now - I apology for not looking closer before. So the main point is that if there was some fixed velocity to some medium: aether in sense of a fluid filling the Universe, the Michelson-Morley experiment wouldn't realize it. Indeed underwater analogue of this experiment also wouldn't indicate such movement - we would need some "flowmeter" (e.g. pipe with turbine) for that. Could we build some "flowmeter" for hypothetical eather? I'm open, but honestly rather very skeptical.

The main reason is that I don't think imagining fluid filling the Universe is the proper intuition - field theories should be rather imagined that the space(-time) is rather a crystal with infinitesimally small lattice constant. In aether view you need space plus the filling fluid, while in field theories you have just space with some internal degree of freedom choosing values in each point - like deflection of atoms in lattice crystal, or values of the stress tensor in each point - which can be smoothen and can be seen as direct picture of ellipsoid field I use.

Considerations looking very similar to ellipsoid field can be already found in fluids: liquid crystals. Precisely, if the molecule is asymmetric, it can be represented as ellipsoid with three different axes - these liquid crystals are called biaxial nematics and there are used quite similar equations, but thermodynamical (parabolic not hyperbolic). Another reason I didn't even mentioned them in the essay (besides length limit), is that I don't see a way to make it viscosity-free, so twist-like waves would always dissipate there...

You have also mentioned Casimir effect as argument for such fluid - I disagree: this energy shouldn't be seen as energy of the lowest state of potential well, but as energy of the well itself: invested while forming it.

Your succeeding argument is dark energy/matter, but I also disagree - you can get the same in crystal/field view. I (and prof. Faber) see them as just thermal energy - we can observe 2.7K EM thermal noise (CMB), but there are also other interactions and their degrees of freedom should also be somehow thermalized - carrying a lot of energy we cannot directly detect. Dynamics inside energy minimum of Higgs potential is electromagnetism: massless Goldstone bosons - the other degrees of freedom are massive and should be also thermalized. Prof. Faber call them alpha waves, I call them deformational dof (of shape of ellipsoid).

You: "I think light can be treated like a classical wave, there is no need to modify it at all but I do not know if this version is compatible with the topological formalism." What do you mean by classical wave? Standard plane waves are completely incompatible with that optical photon can be produced by a single atom and then after years absorbed by a single atom - you need a mechanism to keep this energy localized: to make it soliton.

What direct or indirect consequences would you expect from such "flowing aether"? If there are none (like in field theory picture), maybe it's not worth considering?

Cheers,

Jarek

Dear Jarek

I haven't realized about your last reply. I am sorry for this.

You: Could we build some "flowmeter" for hypothetical eather? I'm open, but honestly rather very skeptical.

The problem of detection is really complicated but in principle it seems to be feasible. My reference 17 (Eq. 14) gives a clue. There are some other plausible proposals for its detection, see C. Christov Nonlinear Analysis 71 (2009) e2028_e2044

As you say, in the present view, space-time is a continuous empty geometrical vessel filled with fields (gauge, fermion, Higgs, electromagnetic). If this view has been useful, I think the opposite should work much better. One can conceive the fluid as space itself and the fields as states of this fluid with solitons (particles) moving through it. So there is no need of assuming space and the fluid as you imagine. Instead, the fluid plays the roll of space and at the same time of medium for solitons and fields.

You: Another reason I didn't even mentioned them in the essay (besides length limit), is that I don't see a way to make it viscosity-free, so twist-like waves would always dissipate there.

Well I think it is natural to conceive dissipation if space is assumed as a fluid, though dissipation will be so tiny that for low energies can be neglected. At higher energies or cosmological distances the dissipation certainly will play an important role. This is my point and this is why I having asking you about dissipation for photon-like solitons.

You: You have also mentioned Casimir effect as argument for such fluid --I disagree: this energy shouldn't be seen as energy of the lowest state of potential well, but as energy of the well itself: invested while forming it.

I haven't work out the idea, but you may be interested in taking a look at the essay of Luis de la Pena and Cetto. They discuss the zero-point field energy in more detail.

You: "I think light can be treated like a classical wave, there is no need to modify it at all but I do not know if this version is compatible with the topological formalism." What do you mean by classical wave? Standard plane waves are completely incompatible with that optical photon can be produced by a single atom and then after years absorbed by a single atom -- you need a mechanism to keep this energy localized: to make it soliton.

Just remember that in reality atoms do not emit light at one single frequency but at different frequencies centered around an average frequency. Although in theoretical matters (for simplification) one usually deals with single frequencies in reality what is measured is an envelop of waves with different frequencies. In the field of optics (or x-ray spectroscopy, etc.) this is very well known, nobody has ever measured a monochromatic wave. The distribution of energy as function of frequency is always localized in a finite region of space and never resembles a Dirac function (one-single frequency). One classical example is the Gaussian packet. This same idea is used in QM. By the way the conception of space as a fluid can make QM local and give a non-probabilistic interpretation to the wave function, so all the mysteries of this theory automatically disappear. This is in relation to your question:

What direct or indirect consequences would you expect from such "flowing aether?

Physicists have been attempting to unify for the last 30 or 40 years GR and QM and many people question whether one of these theories is fundamentally incorrect. I think that the topic of this contest has a lot to do with this problem. As far as I can see considering space as a fluid could solve many of the most important problems in physics but at the high cost of not only reinterpreting well established facts (such as the CMBR, the expansion of the universe, dark matter, etc.) but also dropping GR. As you know relativity treats space as mere geometry and it seems that this view is utterly incompatible with mine (see Christov article).

Cheers

Israel

Dear Israel,

I have looked at the Christov paper and in the only relevant experiment he intends to violate Lorentz invariance by electromagnetism in simple few body systems - you will not convince me to something like that.

I agree to use stress tensor like Cauchy - it is exactly where I get all particles and their dynamics here from (due to the only nonstandard concept added here: Higgs-like potential), but the PDE's are Lorentz invariant and so if one gets violation in their consequences, it means he has made a mistake somewhere, like forgetting that boosts add magnetic field to charges.

The only possibility I can take seriously is a flow of some underlying physics, to which the stress tensor is effective level - but please besides references to difficult to obtain papers, briefly describe concepts/experiments you refer to ...

Cheers,

Jarek

Dear Jarek

As I argue in my essay, the scientific value of a theory resides in the power to explain and reproduce the body of experimental evidence under consideration. One should distinguish between Lorentz invariance (LI) and Special Relativity (SR). LI can be derived (as Lorentz himself did in 1904, and many others even nowadays) from the assumption that there exists a medium for the propagation of light waves (what I called space itself but seen as a fluid not as geometry) which can be assumed to be the preferred system of reference (PSR). This means that the existence of the medium does not contradict LI (This is precisely the discussion of my essay). Let us called, Lorentz approach, Lorentz theory (LT).

On the other hand, SR makes no assumptions as to the medium for light. Actually, SR accepts LI but rejects per se the PSR. In other words, we have two theories that explain the same physical phenomena. However, each theory has its problems. The former has been forgotten because it has not been possible to detect the medium. This does not mean however that the medium does not exist. And the latter, as it is well known within the circles of the philosophy of physics, has logical inconsistencies (paradoxes) such as the Supple paradox, the clock paradox, etc. --unfortunately, most physicists do not even acknowledge them.

So, if both theories explain the same phenomena, in principle, it turns out to be irrelevant which one we chose to work out the calculations of a problem under consideration. Einstein considered the aether superfluous and moved on with his approach despite the paradoxes. These paradoxes could be ignored --as it is actually done-- since they do not interfere with the theory predictions. I have no problem with this.

Nowadays there are many problems in physics, in a certain sense, it is widely recognized that theoretical physics has been in a state of stagnation, no major breakthroughs have occurred for the last 30 years. As time goes by the experimental evidence piles up and adds more to the puzzle. So, some years ago I started to carefully analyze and study the history and the foundations of physics. I found that LT is still valid and that it could be still useful to solve many problems in physics if the medium is reintroduced (you may wish to see my discussion with Daryl Janzen in his entry and mine in relation to the physical interpretation of the redshift). So, in the present state of things, if I were asked what theory, i.e. LT or SR, I would chose to work out the calculations, I would chose LT. Why? because it has no paradoxes and the idea that there is a medium it is helpful to some our present problems. In 1951 Dirac and later in 1965 strongly suggested that the situation in physics in 1905 was quite different than the situation 50 or 60 years later and that the notion of aether could be reintroduced. The Cassimir effect, the Lamb shift and many other experiments strongly suggest that the vacuum has an internal structure.

Certainly, physics has changed since the sixties and we have to update some conceptions. During this investigation I come across with Christov's work in which I found some plausible results. First, based on the assumption that space is a fluid and applying the theory of fluid and wave mechanics, he succeeded in deriving Maxwell equations and Lorentz force formula as integral parts of a major formulation (Eq. 17). This is clearly of great significance. Keep in mind that in the present view Maxwell equations (the classical Lagrangian of the electromagnetic field was inferred from Maxwell equations but is not derived from a higher principle) and the Lorentz force are empirical constructs not derived from any physical principle. Moreover his formulation reproduces the relativistic effects, i.e., length contraction, time dilation, etc., and pave the way for the introduction of solitons as natural ingredients. And above all his proposal fulfills with the principle that the laws of physics should be the same in any system of reference. As he explains in section 6, there is one caveat. Experiments do not measure absolute magnitudes (he called them material variables) but only relative ones (this is why SR has been so successful) and for such reason he reformulates his model in Euler variables. Therefore, since his model explains physical phenomena --just as relativity does--, unifies electromagnetism (he went further and unified gravity and QM), fulfills the principle of covariance and is free from paradoxes I do not see any objection. Your comment "...he intends to violate Lorentz invariance by electromagnetism in simple few body systems..." causes me confusion, why do you argue that his experiment violates LI?

Likewise, I did not understand this part very well: PDE's are Lorentz invariant and so if one gets violation in their consequences, it means he has made a mistake somewhere, like forgetting that boosts add magnetic field to charges. I would appreciate if you could elaborate a little bit further. Do you mean that all equations in physics are PDE and that they should all be Lorentz invariant? How is he violating the fact that boost add magnetic field to charges? I do not clearly see the connection, since he is complying with LI.

With respect to your last paragraph, if you are interested in the detection of the medium I would suggest that you take a look at my reference 17, Eq. 3.14 shows that in principle an inertial observer can determine its absolute speed. I do not know what other concepts/experiments you mean.

Cheers

Israel

Dear Jarek,

Of course mathematics is a good tool for describing of phenomena with the help of formulas. But the problem is with the real models of particles. When the model is wrong mathematics can not help. See substantial model of electron in § 14 of the book: The physical theories and infinite nesting of matter. Perm, 2009-2012, 858 p. ISBN 978-5-9901951-1-0. By the way the problem of electron spin is explained in the book.

Sergey Fedosin