Since I believe that:
1. Gravity is nothing more than an imbalance in electric fields
2. Magnetism is nothing more than a minor effect of moving charges/moving fields
3. Atomic physics and nuclear physics cannot be done right without having the electromagnetism right to start with,
Then it seems clear that the most vital thing to figure out is the business of charged particles and their associated electric fields and how they interact with each other. But either I'm totally lacking in imagination or totally lazy or both those things, because I'm just not certain where to go next.
My present feeling is that what we call magnetism is mostly a simple result of propagation delay, i.e., the effects of the distortion of electric fields as they move through the aether. O.K., so? What do I need to do next?
Friday, November 14, 2008
Wednesday, October 22, 2008
Aether 'Density'
Here's a little pure speculation for you. One can ask, what is the relative contribution of each primary electric field to the medium at a given location? One possibility is that the 'weighting factor' is proportional to the electric field strength at a given location. Since the electric field strength falls off as the inverse square of the distance from the source particle, one would expect pretty big variations in the effective state of 'rest' of the medium and the propagation speed of the medium. In other words, stars (and planets) would tend to carry their own state of rest with them. For example, the dominating medium around the earth would more or less move with the earth, and we might expect to see significant variations in the characteristic speed (speed of light) with distance from the earth.
On the other hand, if there was no weighting factor at all, in others words if the contribution of each field element was completely independent of field strength, then one might expect the characteristic speed to be totally constant and the state of rest to be solely determined by the 'average' state of motion of all particles in the universe.
Now, if the weighting factor were dependent on the inverse distance from the source particle (like the electric potential), then one would expect an intermediate result. For example, the characteristic speed would be nearly constant, varying just a tiny bit near massive objects. And friends, this is precisely what we see. Likewise, the local effective state of rest of the medium would almost solely determined by the average state of motion of all particles in the universe.
Ernst Mach dimly perceived that something like this could be the case. In a sense, local physical laws are determined by the large-scale structure of the universe.
On the other hand, if there was no weighting factor at all, in others words if the contribution of each field element was completely independent of field strength, then one might expect the characteristic speed to be totally constant and the state of rest to be solely determined by the 'average' state of motion of all particles in the universe.
Now, if the weighting factor were dependent on the inverse distance from the source particle (like the electric potential), then one would expect an intermediate result. For example, the characteristic speed would be nearly constant, varying just a tiny bit near massive objects. And friends, this is precisely what we see. Likewise, the local effective state of rest of the medium would almost solely determined by the average state of motion of all particles in the universe.
Ernst Mach dimly perceived that something like this could be the case. In a sense, local physical laws are determined by the large-scale structure of the universe.
Wednesday, October 8, 2008
What About Relativity?
Let's see if I can roughly paraphrase it. The correct laws (equations) of physics ought to be independent of the frame of reference. That, more or less, is the principle of relativity. It appears that the authors of that statement never stopped to talk to the ordinary guys who deal with elastic waves in solids, acoustic waves in fluids, et cetera. Anybody knows that the equations are only going to be simple in the reference frame stationary with respect to the medium of propagation. So you see, we've gone down a bad road. Some smart guys, for example, got completely fooled by the null result of the Michelson-Morley experiment.
You know, I'm definitely not the 'smartest guy in the room', and I've been wrong about lots of things. But I can say these things with honest conviction. I'm not actually a threat to anybody. I'm not in academia. My work is not published in the prestigious journals. I have nothing to lose by being perfectly honest about how I see it. And (scary thought) I just possibly might be right.
Anyway, my advice: don't try to make electromagnetic radiation special. Electromagnetic radiation is a disturbance propagating in a medium. The real task is in trying to understand that medium and exactly how it works. Progress will not be made until we stand toe-to-toe with Faraday and Maxwell and think more deeply about the problem than they did.
One more thing: Maxwell's Negative Energy Difficulty wherein a vector theory of gravity is supposedly not possible? If (as is most likely) there is no separate force of gravity (i.e., gravity is a purely electromagnetic phenomenon), then Maxwell's arguments are without merit. I dare to claim that this, along with the invalidity of the principle of relativity, completely undercuts the General Theory of Relativity, not to mention the special Theory of Relativity.
No shame; we've all gone down bad roads. Now is a good time to exercise a little humility, admit that it was all wrong, and start over again.
You know, I'm definitely not the 'smartest guy in the room', and I've been wrong about lots of things. But I can say these things with honest conviction. I'm not actually a threat to anybody. I'm not in academia. My work is not published in the prestigious journals. I have nothing to lose by being perfectly honest about how I see it. And (scary thought) I just possibly might be right.
Anyway, my advice: don't try to make electromagnetic radiation special. Electromagnetic radiation is a disturbance propagating in a medium. The real task is in trying to understand that medium and exactly how it works. Progress will not be made until we stand toe-to-toe with Faraday and Maxwell and think more deeply about the problem than they did.
One more thing: Maxwell's Negative Energy Difficulty wherein a vector theory of gravity is supposedly not possible? If (as is most likely) there is no separate force of gravity (i.e., gravity is a purely electromagnetic phenomenon), then Maxwell's arguments are without merit. I dare to claim that this, along with the invalidity of the principle of relativity, completely undercuts the General Theory of Relativity, not to mention the special Theory of Relativity.
No shame; we've all gone down bad roads. Now is a good time to exercise a little humility, admit that it was all wrong, and start over again.
Saturday, August 30, 2008
An Idea About Beta Decay
How can we possibly explain the continuous spectrum of electron energies in beta decay without having to invent another particle to properly arrive at conserved energy and momentum? There are two factors that give me hope that a solution is possible. One is the extreme difference in mass between the unstable nucleus and the escaping electron. For example, what was known as Radium E is, in fact, Bismuth - 210. This nucleus has a mass approximately 382,000 times bigger than the electron. Secondly, all atoms in solids undergo thermal oscillations. Thus, a decaying nucleus will have a unique velocity at the instant of ejection of the electron. The velocity distribution of the nuclei may be intimately related to the spectrum of the ejected electrons. This seems worth looking into.
If this is correct, then we would expect to see some much smaller variation in the energies of alpha particles ejected in alpha decay.
If this is correct, then we would expect to see some much smaller variation in the energies of alpha particles ejected in alpha decay.
Saturday, August 16, 2008
Mossotti-Lorentz Gravity
Everyone interested in gravity and the link between gravity and electrodynamics ought to read the 1900 paper by Hendrik Antoon Lorentz. An English translation can be downloaded from the digital library in the Hague in the Netherlands under the History of science and scholarship in the Netherlands. Starting in Section 5 of the paper Lorentz derives two sets of Maxwell equations for gravity based on the idea that gravity is nothing more than a small residual of electric forces wherein the attractive forces between unlike charges are just slightly larger than the repulsive forces between like charges. He gives full credit to Mossotti for this idea and credit to Weber and Zollner for further development. Naturally, the result looks like Newton's Law (like Coulomb's Law) but with extra terms. Lorentz calculated the effect of the modified theory on the orbit of Mercury; it was common knowledge that Mercury's orbit has a slow rotation of the slightly elliptical orbit that doesn't fit Newton's Law. Lorentz needed to select a speed and direction of the motion of the solar system through the medium. [Remember this was just before Poincaire, Einstein, and everyone else decided that they didn't need a medium for light propagation.] Lacking anything else, it seems that Lorentz chose the 'proper motion' of the sun, i.e., the motion of the sun with respect to the local group of stars in our neighborhood of the galaxy. The speed is about 16km/s. The number he obtained for the 'advance of the perihelion of Mercury', was way too small. It is interesting to note that if one uses a much larger value, like the speed of the solar system with respect to the microwave background radiation, one gets much closer to the observed value. There seems to have been only a little follow-up to Lorentz' paper. To me it seems a shame that the whole idea was not vigorously pursued.
Sunday, August 10, 2008
Pointing Out Some Questionable Physics
I think I'll just go ahead and lay out some items to be explored.
1. There are no photons. It all started with a misinterpretation of the results of the experiments on the photelectric effect. As Augustin Fresnel worked so hard to demonstrate, electromagnetic radiation is purely a wave phenomenon.
2. Even though 19th century physicists were unable to grasp it, there is a medium of propagation of electromagnetic radiation. Up until about 1899 it was clear to physicists that any wave phenomenon is a disturbance propagating through some sort of medium ... by definition.
3. There is no such thing as mass converting to energy and vice versa. There is no E=mc-squared. I need to go back and carefully do my homework to see exactly how that odd idea was introduced and try to show that it has no real basis in nature. Just to give one small example, I feel fairly certain that the energy of an atomic bomb can be accounted for purely by Coulomb forces.
4. The tiny 'bending' of light passing near massive objects can be explained by a slightly lower speed of light close to such objects. I think it will eventually be shown that the characteristic speed of the medium is slightly less near massive objects, i.e., there is a dependence on "aether density" as it were. There are undoubtedly no such things as 'black holes'; this is an inadmissible extrapolation (orders of magnitude) from the miniscule observed 'bending'.
5. Lorentz and Fitzgerald will eventually be shown to have been on the right track regarding the odd null results of the Michelson-Morley experiments. There must be a certain physical change in the dimensions of objects moving through the medium. The effect is a result of propagation delay changing the equilibrium spacing of neighboring atoms in a solid. It will turn out that the Michelson-Morley experiment was precisely the wrong experiment to measure the speed of objects moving through the medium.
1. There are no photons. It all started with a misinterpretation of the results of the experiments on the photelectric effect. As Augustin Fresnel worked so hard to demonstrate, electromagnetic radiation is purely a wave phenomenon.
2. Even though 19th century physicists were unable to grasp it, there is a medium of propagation of electromagnetic radiation. Up until about 1899 it was clear to physicists that any wave phenomenon is a disturbance propagating through some sort of medium ... by definition.
3. There is no such thing as mass converting to energy and vice versa. There is no E=mc-squared. I need to go back and carefully do my homework to see exactly how that odd idea was introduced and try to show that it has no real basis in nature. Just to give one small example, I feel fairly certain that the energy of an atomic bomb can be accounted for purely by Coulomb forces.
4. The tiny 'bending' of light passing near massive objects can be explained by a slightly lower speed of light close to such objects. I think it will eventually be shown that the characteristic speed of the medium is slightly less near massive objects, i.e., there is a dependence on "aether density" as it were. There are undoubtedly no such things as 'black holes'; this is an inadmissible extrapolation (orders of magnitude) from the miniscule observed 'bending'.
5. Lorentz and Fitzgerald will eventually be shown to have been on the right track regarding the odd null results of the Michelson-Morley experiments. There must be a certain physical change in the dimensions of objects moving through the medium. The effect is a result of propagation delay changing the equilibrium spacing of neighboring atoms in a solid. It will turn out that the Michelson-Morley experiment was precisely the wrong experiment to measure the speed of objects moving through the medium.
Thursday, August 7, 2008
Neutrinos? You're Kidding Me
I'm certainly not the first person that says that neutrinos do not exist. I'm pretty certain that the invention of the neutrino was one of the big boondoggles of modern physics. I would say that Wolfgang Pauli and the others rushed the solution of the problem of the continuous spectrum of the kinetic energy (or speed if you prefer) of the electrons that emerge from the nucleus in beta decay. At the moment I cannot prove it, but I feel fairly certain that the correct explanation lies somewhere in a proper accounting of all the energy and momentum involved in the decay process without neutrinos. Also, I have not yet found a fatal flaw in the 1956 experiments of Frederick Reines and Clyde Cowan, the first time physicists claimed to have observed neutrinos (albeit fairly indirectly). I am open to sensible suggestions and/or experimental results on either side of the hypothesis.
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