<blockquote id="quote"><font size="2" face="Verdana, Arial, Helvetica" id="quote">quote:<hr height="1" noshade id="quote"><i>Originally posted by Larry Burford</i>
<br />As we approach the proton we would notice that elysons crowd each other more than they did farther away. As we approach the electron we notice that elysons are crowding each other less than they did farther away.<hr height="1" noshade id="quote"></blockquote id="quote"></font id="quote">
This implies that the proton has an elysium-attractive property that a neutron lacks, and that the electron has an elysium-repulsive property. Something is missing; whatever gives rise to magnetic attraction must be at work in this level of scale.
<blockquote id="quote"><font size="2" face="Verdana, Arial, Helvetica" id="quote">quote:<hr height="1" noshade id="quote">This wave disturbance would be a moving pattern of alternating compression and rarefaction zones. The movement would be in one direction (call it an X axis) while the alternating compression/rarefaction pattern would occur in a plane that is perpendicular to the direction of movement (call it the Y-Z plane)<hr height="1" noshade id="quote"></blockquote id="quote"></font id="quote">
Are you sure? On second thought yes, there should be compressions and rarefactions on the transverse plane. However, for transverse waves to happen, don't the particles have to move harmonically? That would give rise to such compression/rarefaction, like the air around a guitar string.
But, where's the restoring force that brings the elyson back to its equilibrium positions? I argued before that elysium can't be as dense as a liquid, so unless that's wrong there isn't any "cohesion".
- ANNOTATION -
Seems I'd actually argued that elysium can't be solid.
Follwing these two assumptions, it can't be gaseous either:
1. Transverse waves are the result of harmonic particle motion, which requires the inertia of the particle, and a force causing a stable equilibrium of particle position.
2. The gas phase is defined by a density below the threshold required to ensure that most particle collisions send the moving particle back where it came from.
Therefore elysium ought to be liquid, and "cohesion" applies.
It ought to also exhibit surface tension; this gives rise to the possibility of rarefied "bubbles" containing a lesser density of higher-energy particles. If there are rarefied regions, there ought to also be compressed solid regions, perhaps with ultradense solid MI regions at their centers to create the graviton imbalance that in turn causes the excess elyson density.
More importantly though, liquid behaviors could explain both the strong and weak nuclear forces. Two colliding nucleons would be cushioned by the fluid between them if they have any substantial approach velocity; unless enough pressure is applied to chase the fluid out from between them. Once assembled, the outside fluid pressure would tend to keep the nucleus together.
Reaching just a bit further, the cohesion property could also be giving rise to the electromagnetic forces. As I understand it, magnets are created by aligning electron spins and/or orbits between atoms in materials that have an natural imbalance of spin/orbit momentum. Such an arrangement seems to create a net flow in its adjacent elysium, like the small currents around a ship's exposed driveshaft.
A flow has to have an intake and an outlet, explaining the dipolar nature of magnetism as the physical pressure of two interacting directional streams of locally moving elysium, each trying to restore a continuously disrupted equilibrium.
- Kevin
