U-PARTICLE PHYSICS HOW MAGNETS WORK

 NAYTRON PHYSICS by Frank R Naypaver

 COPYRIGHT 11-29-06

 In this discussion we will use the ultimate particle to explain why and how magnets work. Magnets discovered long ago in load stones and used by Vikings as compasses, have intrigued man for century. We use magnets every day but man still does not know why a magnet works. Here we will try to explain magnetism from a new perspective using ultimate particle physics .

Ultimate particle physics; or u-particle physics is a term I will use to explain the workings of the universe based on the properties and actions of one type of particle the ultimately smallest particle of mater that In 1947, Cecil Frank Powell and co-workers located what he believed to be Pion Bosons in cosmic rays. Each form had a slightly different mass, all decay in seconds, and all are composite particles made from quarks. . This particle is what makes up protons, neutrons and electrons and holds them together . This particle carries inertia energy of the big bang through the vacuum of space between atoms and all atomic masses. This particle is responsible for nuclear strong and nuclear weak forces, gravity, molecular bonding, radio waves, light, and magnetism. The ultimate particles from here on I’ll call U-particles. The u-particles are remarkably simple and only follow a few basic rules

U-particles are neither created or destroyed. U-particles carry speed of light inertia energy through the vacuum of space between atomic masses. U-particles come from every where and everything in the universe and bombard atomic masses of u-particles from all sides which holds them together as basic atomic masses. When a greater source of u-particles react on a u-particle atomic mass, the atomic mass ejects at light speed the excess collected mass of u-particles as a ring like cloud, of one electron volt thrust , “quanta”, in the opposite direction of the greater source of u-particles, this rockets the atomic mass toward the greater source of u-particles.

Iron and Permanent Magnets; Using these basic rules we can explain magnetism. Magnets a remarkable thing in that they move mysteriously with no strings attached and draw toward or push away from each other like magic. Maxwell tried to explain this by using magnetic fields of force, which to this day only confuse people. To explain magnets let us start with some solid known facts about what makes things move iseaic Newton explained motion as a reaction to a action event , this we know will move things through space, we use it to explain jet engines and rockets, and all other mystic forces do not work in move thing. So for a magnet to move in space it must be acting to a reaction, the trick is to fine what is the magnet using to rocket it self toward a steel plat or another magnet. The u-particle is the perfect answer. U-particles are in everything and all around atoms these particles bombard atoms from all sides and contain them as atomic masses, and contain those masses together as elements in molecular masses, normally the u-particles go about their business, keeping the atoms and electrons in place, but when a disturbance of extra u-particles as quanta collide with these atoms they cause the atoms to collect and eject the extra u-particles as new quanta relaying the disturbance away from the source disturbance, this is how radio wave, heat, light waves, disturbances are passed on through mater. Normally the extra energy u-particle disturbance is from all directions especially from the earth as gravity, and the mater mass of atoms wants to rocket mainly towards the earth. But there are some atoms in elements that react in different ways they are the magnetic elements one is iron it is unique in that the outer orbit of iron has all eight electrons like argon and helium the inert gases, iron when brought near a u-particle source reacts really fast and redirects it’s u-particle ejections in the opposite direction of the source, this rockets the iron towards the source. The permeant magnets are also iron and another element that is missing a electron in the outer orbit like cobalt when heated to high temperatures and cooled in a strong magnetic field they form a crystal molecule structure that has north and south crystal s that rocket toward the middle of the magnet these crystals are locked in the way they re-emit received u-particles and make the magnets molecules only want to eject their u-particle quanta in one direction this makes every molecule crystal a little magnet with the same frequency of collecting u-particles and ejecting them in the same direction at the same time. Since the magnets crystal molecules are all similar when they get near other magnets, the crystal molecule’s atoms eject their u-particle quanta in the north , south, direction as the crystal structure dictates in between these magnet pumping cycles the atoms can eject their quanta away from any other greater source of quanta like earth and are effected by gravity. A permeant magnet is like a u-particle quanta diode when it receives quanta from all around the crystal structure forces some of the quanta to be ejected in a pre-defined direction which we call north and south magnetic poles. These poles are not very strong until another magnet or iron material is brought near them, then the u-particle quanta is forced by the magnets crystal molecules to resonate quanta in the north and south directions, these quanta pulses are relayed though local air atoms and absorbed by the opposite magnet or iron mass and steer the crystal molecules to rocket towards each other, as they get closer they receive more and more quanta pules from each other and steer more of their atoms to rocket their quanta away in a opposite direction of the source rocketing the magnets towards each other till they collide, and their ejected in tune quanta pules drives them together holding them together. Poles that are the same rocket away from each other because the magnets crystal structure force them to eject their collected quanta in a fixed direction, so when magnets of like poles get closer to each other they receive in-sync pulsed quanta from each other and eject it backwards against the source and rocket away from each other. Iron has no coherent crystal structure as permanent magnets do and only act as magnetic in the presence of a magnet, but when iron alloys are magnetized the alloys have different time intervals that they display permanent magnetic properties and return to a non magnetic state. Iron’s crystal structure resinates quanta ejection s similar to a permanent magnets, but has no locked in direction. In a experiment when two permanent magnets are held so they reject each other and a thick iron metal plate is placed in between them, the two magnets stop rejecting each other, and rocket toward the iron plate sticking to it. If in the same experiment the iron plate thickness is reduced one discovers that a very thin iron plate can eliminate the ability of the opposing magnets to reject each other and also not rocket toward the iron plate, in effect eliminating their magnetic effect and only gravity still effects them . What this experiment shows is that it takes a specific quantity of iron atoms to react to the magnets ejected quanta, the iron atoms must line up and pass the collected quanta disturbance pulses on to the opposing magnets, a lesser number of iron atoms do not relay enough of their own collected quanta on through local atoms to over come the magnets fixed crystal molecule’s quanta ejections enough, to cause the magnets to reverse and eject their quanta away from the iron plate which would rocket the magnets towards the plate, if the plate is thinned even more the magnets begin to oppose each other again. In another experiment where we bring a stronger magnet together with a weaker magnet we discover that the weaker magnet well attract and stick to the stronger magnet no matter what poles are put to gather. This shows that the overwhelming quanta from the stronger magnet can force the fixed crystal structure of a weak magnet to eject its quanta in a different direction. A strong magnet is due to the magnets successful molecular crystal saturation and alignment at its construction. A strong magnet well have a high percentage of crystal molecules to atoms. A weak magnet will still have a lot of iron or other material not in crystal form this leaves only a few aligned magnetic crystals in the magnet mass to act as a permanent magnet , this could be from the magnet alloy not having the right mixture of materials and or alignment. Heat is another thing that effect magnets if you take a good magnet and heat it red hot the crystal structure will break up and destroy the magnet .

Electro Magnets; After the permanent magnets we have the electric magnets that use the movement of electrons through a wire to cause quanta to bombard a iron bar that becomes a magnet. When electrons move in a wire they are force to do so by the presents of extra u-particles quanta passed through the vacuum between wires atoms. This extra quanta become the greater source of u-particles for the loosely held wire atom electrons and they rocket themselves off toward the extra quanta source. The wire atoms are huge and massive so the ejection of light speed quanta has little effect on them unlike the light weight electrons which move easily when struck by or ejecting u-particle quanta. When a lot of electrons move together in a wire as current they line up behind each other like a train, passing the extra u-particle quanta through each other so the front electrons are the greater source of quanta for the further back electrons, which collect the u-particles from the front electrons then use them to rocket through the vacuum between them up to the front electrons. The extra quanta that would cause electrons to move could come from a magnet passing near a wire, rubbing a wire, quanta waves passed through air atoms as radio waves, attaching a wire to a electron charged storage device like a battery, capacitor, fuel cell, or a potato. The electron is natures way of moving power around. When electrons move in a wire u-particle smoke ring like quanta are relayed parallel with the wire but quanta rings radiate out of the wire perpendicular to the wire. This is why iron fileings form rings around a wire with current flowing in it, the fileing are hit by the expanding out side edge of the relayed quanta ring disturbance. The fileings collect u-particles which they relay out as more quanta rings which effect the other iron fileing causing them to move forming the iron ring patterns around the wire. Maxwell claims these are evidence of the mysterious magnetic force rings, when they are really just u-particle ring waves radiating out perpendicular to the wire colliding and reacting with iron fileings. When the wire is coiled around a iron bar the u-particle quanta ring radiate the iron bar in the same way they did the iron filings. The atoms in the iron bar now rocket toward each other , expelling the extra quanta out towards to the ends of the iron bar. When another magnet gets near this electro magnet it receives quanta from it and rockets itself towards the electro magnet the closer it gets the more quanta the magnet receives and the stronger it well rocket towards the electro magnet. So what can we say about magnets. Magnets like iron metal, are not very magnetic until they get near a u-particle source which supplies the magnetic material’s directional quanta emitting crystal molecules, with the energy and mass to rocket it self through space.

Using u-particle quanta and Newton’s action reaction laws we have the only logical explanation of how magnets move them selves and other mater in space by rocketing them self towards the greatest u-particle source relayed to them through surrounding atoms. U-particle physics can explain how inertial energy of the universe moves through mater as gravity, light, magnetism, energy from vacuum, dark mater, black holes and more. The u-particles do exist we have pictures of the u-particle quanta rings, polarizing light experiments prove u-particle quanta ring are the reason one can polarize light and radio waves. Atoms are not the smallest particles of mater we know this because we smash them into smaller pieces in cyclotrons. U-particles are the smallest particles of mater and can not be exploded or smashed into smaller particles. When a atom collects u-particles through the vacuum of space between atoms, relayed from surrounding atoms the extra inertia they impart to the atom allows the atom and electrons to refuel it self with light speed inertia so it can continue to explode quanta from the atomic mass and rocket towards the greatest source of u-particles.

 Magnetism can be explained by similar quark decay, with magnetite crystals expelling bosons at the speed of light producing movement in space. but now we are dealing with a select group of atoms and molecules. that gather quanta quarks from all over and because of this group's proton, neutron lattice structure, the bosons gathering over time build into quarks, only to decay again discharging boson clouds at the speed of light, this time in a controlled direction causing a reaction. Allowed to move freely the magnet collects and readmits quarks burst from the earth, that reaction aligns the magnet in a north and south direction. When two like poles of a magnet get close to each other they repel, because the received quanta, and the emitted quanta are toward each other so they focus most of their quanta emissions on each other, this builds up and they rocket away from each other. When two unlike poles meet they absorb each others quanta emission and focus them away from each other driving them toward each other. The atoms of a magnet handle the quark quanta encounters on an atom to atom basis and really act more like a magnetic laser absorbing quanta beams and readmitting them at a different frequency in one direction producing motion in space. So magnets are really magnetite crystals, rare earth magnetite crystals are purer and stronger. Experiments can be performed to support this. If you take three round washer like magnets with holes in their

centers

and poles on top and bottom with poles opposing each other, vertically stack them over a wooden dowel struck vertically in a block of wood. Slowly spin the bottom magnet washer and you'll see that the top hovering washers, are not trying to spin with the one you are spinning, if magnetic fields were responsible for the magnet separation you would think the whole stack would spin. So this tends to show that the magnets are riding on a flow of something, like a beach ball in a stream of air from a vacuum cleaner in a Sears vacuum cleaner demo. If you spin the bottom magnet at a constant faster RPM giving angular momentum to the flow of particles the other magnets will begin to spin. Another simple experiment is to take two fairly powerful magnets hold them so they appose each other then move a metal drawer divider or similar thin metal plat between them. The magnets will instantly attract each other. The fact that the magnets change from opposing to attracting would support the quanta emission theory where the iron atoms absorb and change the readmitted quanta to cause the magnets rocketing away from each other to suddenly rocket toward each other. The thickness of the metal can be reduced till the magnets quanta is fully absorbed or to iron foil where little effect is noticed. Time has not allowed me to do the math, but one might discover some unique relation of numbers of iron atoms to magnetic quanta emission using this approach. Another not so simple experiment is to take a three foot square one and half foot thick block of steal, place two compasses about one to two feet on its' far side then move a small magnet back and forth on the near side of the steal block. You'll see that the compasses follow the movement of you're moving magnet even through this massive steal block. It's not logical that magnetic fields from your small magnet a foot away could magnetize this entire massive steal block to effect the compasses. It is more likely that the quanta beams are being relayed from atom to atom emerging from the block striking the compasses needle which collects quirks, blows the excess off as the crystal lattice dictates, the reaction to this then moves the needle on the compass. In experiments where iron fillings are used to show the existence of magnetic fields what we're really seeing is the secondary effect of emitted quanta beams collecting on the iron filings, being re-emitted from the fillings atoms in a particular direction causing the fillings to move into observed patterns. Consider a ball constructed of flat magnets so that the whole out side is the same pole as the inside. A card board ring is cut and set around the balls equator. Iron fillings are sprinkled on the card board, they will arrange them selves into sperate rings out from the balls surface. This is the same no mater how the ball is turned so we could conclude that the magnet ball now look some what like we picture a atom, with its' electron shells around it. At any rate the iron filling shells don't intersect, but show shell layers spaced out away from the ball, this is easier to explain as iron filling reaction to quanta beam emission absorption and readmission, then field emission. Particularly when we have no reason for fields producing iron filling movement in space

Consider a ball constructed of flat magnets so that the whole out side is the same pole as the inside. A card board ring is cut and set around the balls equator. Iron fillings are sprinkled on the card board, they will arrange them selves into sperate rings out from the balls surface. This is the same no mater how the ball is turned so we could conclude that the magnet ball now look some what like we picture a atom, with its' electron shells around it. At any rate the iron filling shells don't intersect, but show shell layers spaced out away from the ball, this is easier to explain as iron filling reaction to quanta beam emission absorption and readmission, then field emission. Particularly when we have no reason for fields producing iron filling movement in space.

Static electric charges appear when electrons are forced onto a abject in a confining medium. This is usually a object that is insulated from other objects trapping the extra electrons. In this theory using our atom naytron quark receive and re-emit rule. We can visualize that the extra electrons will force themselves to the outer surface of the objects aligning their relay output with the excess flow of boson naytron clouds from with in the charged object. If we experiment by charging two similar size objects (like two standard size balloons), we well find that these objects repel each other when close to each other. But if we hold these same objects near a vary large object like a wall they will be attracted to the wall and may even spark to the wall. This could be enplaned by the viewing the two similar size balloons boson outputs as the balloons approach each other. In this case the internal boson output flow of each balloon is greater then the boson flow received from the other balloon this greater flow steers the out put of the surface atoms and electrons, keeping their output direction toward the other balloon. The other balloon is doing the same thing. Received boson clouds build to quarks to slowly to change the output direction of the atoms and electrons they hit the excess quarks inter the system and increase the out put flow of the balloons toward each other the inertial reaction to this pushes the balloons away from each other. When the balloons are brought close to a larger denser object like a wall the internal output of atoms in the balloon are not great enough to keep steering it's output of boson clouds toward the wall. The flood of bosons from the wall over come and steer the balloons boson output away from the wall the balloons inertial reaction pushes the balloon against the wall object.

 Strong and weak magnet experiments will yield the same results as static electricity. With the exception that magnet (iron -Fe-) atoms can have preset steering of their boson outputs. Consider iron the main atom of magnets. Iron (Fe) atomic number 26 atomic weight 55.847. Note that iron is unique like helium, argon, and neon all with their outer electron shells complete, that is they have the maximum allowed 8 electrons. Looking at the nucleus of iron we note after allowing one neutron for proton there are 4 left. In conventional atomic theory this may not mean much, but is very significant in this theory. As mentioned earlier this theory defines a specific atomic structure to proton, neutrons, and electrons of atoms. So in this theory the 4 neutrons force the iron atom in to a unique structure.

Earlier we talked about the atom nucleus, protons and neutrons absorbing and re-emitting naytrons, in boson clouds along with normal internal naytron decay, output from the nucleus resemble expanding smoke rings coming out in the +z,-z +x-x +y-y axis directions, the rings expand radiate out intersecting each other. Lines drawn from the intersecting ring points form a 5.5X10 (18) cubics per second output. the 4 extra neutrons position themselves into the middle of the -x, +x, -y, +y sides increasing their boson cloud output. The +z and -z axis output is weakened so the Fe atom output resembles a box with it's opposite ends open . Electrons of the complete electron shells redirect the boson flow streaming from the corners of the box at 45 degree angles to the center. The open ends become the atoms north and south poles, the inertial thrust would be equal, but the first shell of atoms only hold two electrons and in iron they can shift sides, polarizing the flow to produce north or south sides. If the iron atoms are arranged in a ordered crystal structure we get a magnet.

Two similar magnet poles will repels each other by not flooding the atoms with enough naytron bosons clouds to shift the electrons in the first shell but if a stronger magnet is used it can force the weaker magnet's first shell electrons to shift to the other side shifting poles so the magnets instead of repelling, attract each other. This is why in magnet experiments the magnets locally defy gravity but the whole magnet system stays on the table held there by the output of earth's mass. Some simple confirming

experiments can be done. One is, take a .040" inch thick or more, plate of steel around 3 inches by 4 inches , and hold 2 similar magnets so they oppose each other S,S or N,N now pass the steel plate between them. Result is the two magnets now attract to the plate of steel. The steel plate must have shifted to N,N if the magnets were S,S. The N,S relation is lost. Further inspection reveals that the N,S,N,N,S,N pole relation is still there. Only atoms a few thousands deep, on one side of the magnet have been effected by the steel plate. Another similar magnet brought near the outer sides of the magnets sticking to the steel plate are repelled or attracted normally, as if the magnets weren't stuck to the plate. This shows that what ever the reaction the plate has with the magnets does not effect any more then surface atoms. Further if a .010" inch thick steel plate is used instead of the .040"inch plate there is not enough atoms to force the reverse of the two magnets, and weakened, will still repels each other.

 Experiment no. 2 take a strong rear earth magnet and bring it close to a standard weaker magnet and N,N will repels at a distance, but on forcing them together the magnets will begin to attract and stick together. Exploring the weak magnet with the strong magnet reveals stronger magnetic forces 45 to 51 degrees off the side of the weak magnet. So the poles of a magnet most be shifting at the atomic level. and the atoms inertial thrust is at a angle to the atoms north, south orientation.

Experiment No. 3 Take a small magnet and amply pour iron fillings all over it. Result you see a rounded iron ball with apposite flat sides on it. In between the flat sides you note a line of north south collision, around the iron ball. Translating this in light of this theory what we're seeing is the magnets artistic rending of it's individual atoms. the iron filing trying to align themselves with least resistance in the quanta flow coming from the magnet. Next the line of north, south collision, shows that if you had just two magnetite atoms their quanta flow would force the first shell electrons away from each other forming a two atom north south pole magnet.