The Feynman force is the E in E=MC(2) [squared] -- the measure of the power of light. When light travels, it applies this force to Einstein's Fabric, resulting in its incredible speed. But half that force goes into the fabric that light pushes itself off of. Not so different from the way a sailboat takes the energy of the wind from one direction to propel itself in another by pushing on the water with it's keel. Some of the wind power goes into the water, some goes into pushing the boat. When light is bound in matter, that energy stays where it is applied -- in the atom. Light applying its force to light. That's why the C gets squared in Einstein's fundamental equation. Matter IS light. And so are we.
Hawkrings are gestating in black holes right now, and will emerge as the building blocks of atoms for the next generation of life in Hawking Rebirth, what we now call the big bang. Atomic structure is so simple a child can understand it. Atoms are not as empty as we think. Our view of the center of an atom containing it's whole mass is a misunderstanding. The center is only the center of an atom's mass -- and it's not as tiny as we think. Relativistic effects in accelerator experiments make it very difficult to target the nucleus, making it seem tiny. The nucleus is actually a physical model for an atoms electron surfaces. Atoms are chock full of guess what? Light!
This is not the Onion. It is the Grand Unified Theory we just found. It's called Lorax Theory.
The explanation we've heard all our lives, and most of us still believe. That light is "pure energy -- it moves by itself", is only a half true. Light moves on light. Mass is a quantity of light energy bound to Einstein's light fabric. The binding effect is inertia. If we apply a force to a still object, mildly relativistic effects change the motion of the light fabric creating a momentum wave that sustains its motion. Gravity is another mildly relativistic effect that operates just like inertia and momentum. Say goodbye to the imaginary graviton.
Relativistic effects can be explained and understood in 5 minutes with slinkys. My hero, Einstein, got it right. How he understood relativity without realizing the mechanism that makes it work is beyond me. Increased mass, time and space dilation(in all three dimensions), happen when relatively more energy of a mass is spent in effecting the mass/fabric connection, and less energy is left over for atomic function. Relativistic effects are all around us.
Everything we know about matter, including the most inexplicable quantum effects, can now be easily understood. And all the effects arise from a single force, the Feynman Force. The driving energy that powers individual photons. The combination of photon interactions that emerge from the power of individual photons reaching out and touching others, creates what we call the 4 fundamental forces -- I call this the Dylan Effect. The Feynman Force generates them all and makes everything we know possible.
The universe will be reborn again and again. When all the energy burning in all the galaxies is spent, Gravity won't have to pull all that mass back together. The matter's energy will turn back into free moving light. The only matter that will still have mass will be in black holes. Which will all join together forming a single huge black hole -- not a singularity. It won't explode right away. It will grow from its Hawking Rebirth into a universe just like the one we are in now. And lots of other lucky people living on lots of other planets will have the pleasure I have had over the past month -- to be the first one on their planet to understand the simple beauty of how it works.
Below is Faraday Rules -- Primer on Elemental Nuclear Construction. A simple instruction manual on how atoms are built from the simple structure of protons and neutrons. Atomic structure is beautiful. You can see how the shape of each configuration reflects its elemental properties -- it's like building with blocks. I'll show you the elements I have figured out so far. But most of the periodic table is waiting to be revealed.
Elemental Nuclear Construction
Faraday Rules
- A Hawkring is a single photon whose energy level was reduced in the energy starved center of a black hold in the previous universal generation. The photon joined at the head and tail. Hawkrings form a circle with a rotational direction – left (positive) or right(negative). Both types have an input and output direction. In atomic function, Photons pass through these rings and emerge with the Hawkring’s rotational orientation. In atomic construction, the opposite orientation of the two types regulates the possible ways Hawkrings can combine.
- In initial bonding during Hawking Rebirth(currently known as the big bang), Hawkrings can join stably in only one way. Opposite types facing opposite directions – a left and right Hawkring come together, if the left turning Hawkring’s output flow is north, the right’s output flow is south. They join side to side with input/output directions parallel.
- Bonds form when a photon is passing through a ring of either type. Then while still passing through that one, also goes through the opposite type in the correct direction. The two Hawkrings are drawn together, the photon wraps it self around both rings and the "gears" of all three are engaged, they share energy and equalize their energy levels. This process continues untila stable formation is created.
- Only two stable formations occur. A circle of 8 alternating (L, R, L, R, L, R, L, R...then the last R joins the first L) Hawkrings – a neutron. Or the same formation with an additional Left Hawkring in the center, bonding to the 4 Rights in the larger circle – a proton, hydrogen nucleus. Both structures are flat, in one plane. All the right(negative) rings are facing one direction. The left(positive) rings face the other.
- Almost any combination of protons and neutrons, is possible in supernovas if the arrangement is electrically stable (that is, the number of protons and neutrons are balanced). Although perfect balance is not absolutely necessary, as evidenced by Hydrogen and Silicon. To bond, opposite type Hawkrings must have the orientation stated above. They don’t have to be parallel though. A north output facing Left, can bond to a West output facing Right if the bond is at the northeast corner, where the two meet. If the Right was facing East in that configuration, it wouldn’t work.
Below are a neutron in its natural shape. As it is when it is not bound to anything. Next is a proton, the center Left Hawkring binds to the 4 right Hawkrings, creating the natural square shape of an unbound proton. Next is a neutron in the square shape it will often assume when it is bound to protons and other neutrons in a nucleus.
Helium Formation
Helium starts out as a string of 4 neutrons and protons(2 of each). Then the string wraps around and joins end-to-end, forming an open cube. This is basis of many atoms, including aluminum and calcium. Which are pictured further down.
On the bottom right is a very basic sketch of how a nucleus interacts with right and left spinning light in expressing the electric and weak nuclear forces between the nucleus and its electrons. An electron is a single right spinning Hawkring. The blue lines are the left spinning light attached to the left spinning Hawkrings in a nucleus and in an electron. The pink lines are right spinning light attached to the right spinning Hawkrings. When right and left spinning light meets tail to tail, the tails grab onto those from the opposite direction and bind, creating the electric nuclear force. When right spinning light meets tail to tail with left spinning light, the tails push each other away -- the weak nuclear force.
Only a few strands of light are shown here to demonstrate the concept. A real atom would have a large number of these strands, filling the space around the nucleus and the space around the electrons.
[A good chemist could figure out the whole periodic table in a few days – anyone interested, please do. I’ve only had time to figure out the ones that seemed obvious
Basic Forms
In a proton, the center positive Hawkring is bonded to the four negatives. This gives a proton a square shape, and creates a tendency toward square configurations in atomic structure. Especially in large atoms. In some of the lighter elements, more open structures occur and the greater flexibility of the neutron allows for nearly spherical shapes, such as those in Carbon, Nitrogen, Oxygen, Fluorine, Neon.
Probably all elements above Neon are built of cubes. Except Silicon – see below.
Spheres
Carbon is a hexagonal ring of six alternating Ns (neutrons) and Ps (protons) that initially form in a line, then join end to end to form a circle. Then two Ps and one N join on the top and one P and two Ns join on the bottom.
Hex ring and Carbon top and bottom
Nitrogen, Oxygen, Fluorine and Neon all have a similar ocagonal ring of 4 Ns and 4 Ps. Each of those has either 3, 4, 5 or 6 (Ns and Ps) on top and bottom. I haven’t gone through all the details of how those Ns and Ps fit on top and bottom on the spheres. But carbon works and the others will too. The Ns and Ps that fit into the rings don’t have to match up exactly with a whole N or P in the ring. The Hawkrings just have to have an opposite type of ring to bond with. All the Ns are facing inward on the spheres.
The component combinations in Oxygen are shown below. First an octagonal right forms, similar to the hexagonal ring in Carbon. Then on the top and bottom of that is a combination of 2 neutrons and protons that bond to the edge of the ring. Two protons bond to two opposing neutrons in the ring. Then two neutrons join the ring, slightly off center compared to the protons. The corners of the neutrons and protons meet and bond in a square in the center. The top and bottom are identical. But the two protons on top and bottom are not joined to the same neutrons in the ring. Each set of opposing neutrons in the ring has a set of protons bonded to it in either the top or bottom configuration. This configuration results in the roughly 104 degree angle between two pairs of Oxygen electrons that bond covalently with hydrogen atoms in water. In snow flakes, where the Oxygen/Hydrogen bonds are between single electrons, one of the electrons bonded to a proton in the top of the formation forms a 120 degree angle with either of the electrons bonded to the protons in the bottom formation.
Oxygen(8) Octagonal ring and top/bottom formation
Combinative Squares
Open Cube and Open Tube
If you take 2 neutrons and 2 protons and line them up in an alternating (N, P, N, P) side-by-side row, then bring one end around to the other and join it (Helium), you have an open cube with only four sides. Open Cubes can join with each other on the open ends if each N is adjacent to a P. This is an open tube. A 2 tube cube is Beryllium.
Aluminum -- Stack 3 open cubes to form a 3 open cube open tube. Add four more open cubes to the four exposed sides of the center cube, with the outermost side of each of those four cubes being open – Aluminum. Light, but with a shape providing nearly perfect bonding properties in all three dimensions.
Below is a picture of the Aluminum Nucleus. There are six open cubes, with two protons in each, and another proton and neutron in the center.
Another example of a strong light element is Calcium. Form a 6-cube long open tube. On the 2nd and 5th cubes, add two open cubes opposing each other on opposite sides of the tube, with both sets in the same plane. This shape is longer than aluminum and doesn’t have as perfect a 3 dimensional bonding formation. It is maximized for lengthwise compression strength and lightness. The confinement of the formation to two dimensions might explain the splintering tendency in long bones. Probably they are arranged to have better three dimensional strength in skulls and the ends of bones. The 4 attached open cubes could go anywhere. But it is more likely to form and be stable if there are two sets of two cubes opposing each other.
Solid(Magnetic) Cube
A six sided cube is probably common in many medium weighted elements. There may be more than 1 form possible, such as an electrically unbalanced cube, if it is combined with others that balance it out. The simplest would form by adding a proton and neutron on top and bottom of an open cube with the extra proton’s output end facing toward the center. The center Hawkring in a proton is more open than those in the 8 surrounding Hawkrings. This makes these cubes eject a connected stream of positive spinning photons through the opposing neutron. The ejected photon streams escape the atom’s space. This seems inefficient for atomic function in general. Because those photons are needed to bind electrons to the nucleus. However, that is exactly what happens when the highly magnetic elements (Iron, Cobalt, Nickel) are cooled under the influence of an aligned magnetic field.
Here is how Iron is constructed. This, and other highly magnetic elements, is likely formed in an aligned magnetic field in a supernova, which favors the configuration I’ll describe. Take the magnetic cube just described, with the center proton, of the three in the cube, closest you. The other two protons are on your left and right. Add another identical cube(to the neutron on the side farthest from you), but rotated 90 degrees so this one has a proton on top and bottom, and still has one on the side close to you. Add three more to the farthest side from you, turning each likewise so you have 5 in a row. Each with a positive proton facing away from you. On the middle cube, which has protons on the sides, add an open cube to each side, so they are opposing each other. On the top and bottom of the same cube, add to each another solid cube with the 2 protons pointing inward. This is Iron.
This has a configuration similar to Aluminum, but it’s made of solid cubes, and longer. So it’s heavier and stronger. But the fascinating thing is the magnetic configuration. At the center cube, positive photons will be fed into the center cube from the sides, top and bottom. The positive photon flow in the five cubes in the center are all pointing the same forward direction. All the positive Hawkrings direct positive photons either toward the center or out the front of the atom. This configuration is a perfect positive photon ejecting machine. If iron goes from molten to a solidified state in a strong magnetic field, these atoms will align in the same direction and (even after they’re cooled and removed from the field) feed each other in cycle that generates the magnetic lines we seen in iron filings. The filings have the same design and aligh themselves to the positive photon flow. The magnet ejects left spinning photon chains out one end and into the right spinning photon fabric we live in, where they can’t propel themselves. They get bounced around till they find the only place they can go – the input end. Once they find it, the flow is maintained in a cycle. If Iron or other magnetic elements are cooled away from a magnetic field. They don’t act in concert. But the effect still happens in individual atoms.
Iron(27) Fe Formation
Compacted Cubes and Layer Cake Cubes – Compaction
In very heavy elements, I think something happens that allows more than six protons and neutrons to fill a cube. This likely happens at least in the precious metals -- Silver, Gold and Platinum.
Copper, Silver, Gold, Lead and Uranium and Mercury. Compaction. This wasn’t obvious at first, but it must be true. The atomic numbers for the super heavy metals don’t work out to a rectangular cubic form using solid cubes. But they must have it. An atom’s electron surfaces have the shape of their nucleus. A cubic formation would explain their softness and conductive properties. A flat electron surface generated by a cubic formation doesn’t allow a strong interlocking bond such as that in Aluminum. And the electrons in a cubic would be in a plane between atoms so their photons flow easily.
Here’s how I think the compaction sequencing works. A neutron slips around a proton and two of the neutron's opposing right Hawkrings bond to two of the protons opposing negative Hawkrings with two of it’s opposing positives forming a cross. Then another neutron slips around that formation and bonds to both(4 more bonds). Now it’s sort of a star looking formation with positive rings on each of the six corners. This might also be possible with 3 neutrons forming a similar star with negative rings on the outside. But that doesn’t seem as likely because the electrical balance would be so far off.
Now you build boxes around these cubes and join them, figuring out a way for the thing to be reasonably balanced as it is constructed. Each adjacent star shares a neutron or proton wall between them. The cubes are integrated, unlike the solid cube formation in Iron where a whole cube joins a whole cube and there are two hadrons(protons or neutrons) in the walls between cubes.
I think Zinc may be a perfectly formed 2x2x2 compacted cube. By the way, anything that has has a silver color in pure form, likely has a nearly perfectly balanced electron surface. Copper and Gold, for example are yellowish. Their electron surfaces are probably imperfect in some way, which bends the light it reflects sort of like a lense or a prism does.
Copper seems likely to be a 2 x 2 x 2 compacted cube. With one cube having only a single extra neutron in it's center, rather than a star with two neutrons and a proton. That cube would look sort of like a layer cake. Bonding, I think, to the middle Hawkrings in the hadrons in the cube walls.
Silver must be 2x2x3 compacted cubic. Perhaps with 3 layer cake cubes in the three of the cubes. I guess that these are in two adjacent corner cubes on opposite ends of the 3 cube long formation. And the center cube opposite those are layer cakes. This seems the most balanced formation, giving it a perfect surface along two of the four long lines in the formation, resulting in its color. I'm unsure though.
Platinum, Gold and Silver are all next to each other on the periodic table -- 78,79 and 80. The first two are likely an identical rectangular cubic, but with layer cakes in places that cause their color differences. Platinum closer to Silver, and Gold closer to Copper. Maybe they are 2x3x3. But I haven't had time to calculate that. If someone doesn't beat me to it, I'll come back to this. Mercury must be the same, but with one or more additional cubes sticking out of one or more of the flat surfaces. This would explain why it stay liquid -- it can't get a good bond unless it gets very cold.
Chromium may be a perfect 1x6 compacted cubic.
Misaligned Formations – Silicon
Often, protons will come together in a nonsymmetrical way – where the square corners are not aligned. When I looked at what would happen in that case, I came up with what must be Silicon. Take two protons and join them side to side so that two corner Left Hawkrings bond to the the two center Right Hawkrings next to those. Now try to grow this structure so that it is reasonably balance the whole time. I see only one likely stable formation. That looks something like the diagram below, with Xs being protons and Os being neutrons.
This formation is an imperfect flat hexagon. It can't bond well to another of it's kind at the edges well. Other elements are needed to fill in the gaps. Whatever else, besides Silicon, is in Mica must fill these gaps in a flat way, so that that the hexagons are bonded together in sheets and can join face to face.
Of course, all the formation will not be perfectly symmetrical. I think Silicon makes up a huge percentage of the earth's crust. Lots of imperfection in building atoms. But anything that doesn't emerge to a stable atom probably falls apart and gets used to build something that works.
Can cubes combine in misaligned arangements? Probably they do. But I haven't worked any of them out yet.
If anyone has the inclination and time to work out some more of the table, I could really use the help. Also, I've probably made some mistakes and would be happy to hear about those too. If anyone leaves comments, I'll try to reply to those in the mornings and evenings when I'm not at work.
Thanks - Sneelock