Percolation Builds a Tessellated Waveguide

 

Figure 1: I usually make my own graphics, but today I’m lazy and have used a CC share. It’s probably better than what I would have drawn 🙂 .

Quantum percolation builds a tessellated waveguide in aether. It stops expanding when, due to the cyclic nature of the source, it “runs out of time”, and so it exactly corresponds to the geometry of the wavelength of the energy.  Partial tessellation occurs in both the whole field associated with the wavelength,  and the individual self assembled percolation paths of atom-level energy transits.  The former builds a waveguide for the specific wavelength of the transverse wave, while the latter drives quantum entanglement.  The former is refracted transverse energy momentum, while the latter is longitudinal and angular-momentum driven by percolation. It is important to note that the transverse waves themselves are constituted from longitudinal percolation paths. The difference is that refracted transverse waves are less likely to engage in the Wilburforce pendulum effect associated with a single atom or photon.

Quantum entanglement happens when the transmitter is particularly matched to the aether’s crystallography.  This happens best when the crystallography of the transmitter is a hexagonal crystal. The outer boundary of the tessellation confines refracted transverse energy momentum, while entanglement is caused by longitudinal and angular-momentum driven by percolations at the exact geometry of the atoms involved (or photons).

For a couple years, I have pondered the mechanism that connects the percolation paths that drive atoms at the nano level, with the outer geometries of the transverse wave that results from the self assembling percolation crystallography.  Then I stumbled upon the partially tessellated hexagon geometry (written up in Mathematics Magazine some years ago).  It’s irreptile self similar assembly, and now makes the theory internally consistent.

The partial tessellation is very important, because it creates a very strong refractive discontinuity to build the waveguide (like an impedance boundary in electrical speak).  At the nano scale, the tessellation is confined to the longitudinal moments driven with angular momentum as a result of the percolation paths of the crysallographically defined network topology of the aether.  This aether is what some are starting to call a quantum field.  But, it’s just crystallography, like lattices built of arrangements of atoms.  So, mass is intrinsically connected to energy transit paths that are simply an extension of the crystallography into “space”.

Why would we ever have conceived of a different picture than this?  It extends the *real* nature of our environment in a very localized way, devoid of multiple universes and extended dimensions and projections of this or that, or holographic nonsense. It’s very concrete, and very Tesla-like. A quantum signal, a reciprocating signal responsible for quantum entanglement, is a longitudinal percolation with angular momentum. Its cascade of tessellation enlarges to exactly match the atom or photon with which it entangles.

Note: the author is a writer on technical subjects in some areas, of novels, and of other literature, but does not have any formal credentials related to the medical field, or in physics. Thus, this all constitutes an opinion of what might be possible, based on his own hobby-level knowledge quests.

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Aether Percolation is Longitudinal, with a Twist

I have been covering the magic angle of superconducting and entanglement generating gr@phene in the past few posts. The magic angle, which is 1.1 degrees, is the same for superconduction as it is for entanglement generation. This puts the two phenomenon (entanglement and superconduction) on par with one another, meaning that both are classically driven mechanisms. If superconduction can be described classically, then by virtue of the common magic angle, so too can entanglement be described classically.

There is a pun in the title.

For whatever reason, aether percolation requires a 1.1 degree entry angle. The dipole moments of the originating crystal must be directing the flow of energy, but that direction (for whatever reason) needs to be biased with a slightly non-linear flow in order to induce self assembly and propagation in lyotropic aether. So, the energy becomes a tight spiral or “vortex” of percolating moments of energy-momentum in the aether.  The natural mode of this vortex is in longitudinal moments of energy, but these longitudinal moments are induced to have a very slight boucing action inside of the waveguide of the originating crystal lattice, and subsequently of the lyotropic aether.  

It is the idea of aether-scale/ atomic scale percolation that is responsible for the seeming invisibility of the energy forces that connect entangled objects.  Most lab measurement devices depend on the “human scale” macro world measurement schemes of charge, voltage, current, and such, which require a build-up of many energy moments in order to be detected at all.  The tiny circuit flows of lyotropic aether traces or filaments are undetected by lab devices built to measure built-up charges and transverse waves.

The transverse waves we normally detect with conventional equipment are directed by the waveguide of the larger cross-section of bunched filaments in the aether, as compared to a single filament, due to the well-known pinch effect and the tendency for bunching to occur within many closely-packed traces of percolating energy.  Inner vortexes tend to pull outer ones along, until a (human scale) tranverse wave can be guided by the composite alignments.  Most of the energy is tranferred by the secondary wave (the transverse wave) because the magic angle restricts the direct-flow energy to a few moments (we may call them “photons”) that are in alignment with the crystal – while the balance of the energy is transferred via the waveguide effect and the resulting transverse form. The waveguide mechanism is refraction, which creates a so-called discontinuity in the aether, and supports the transverse flow of energy. This discontinuity is directly analogous to the discontinuity that exists at the ends of resonant antennas.

Note that the base mode for propagation in the outer-band refracted transverse wave is also longitudinal, consisting of many refracted slow-c (amorphous-like) filaments whose energy is in the form of native longitudinal force. It is the larger waveguide of the composite, rather than the singular waveguide of the aether trace, that guides the transverse wave.

Note: the author is a writer on technical subjects in some areas, of novels, and of other literature, but does not have any formal credentials related to the medical field, or in physics.  Thus, this all constitutes an opinion of what might be possible, based on his own hobby-level knowledge quests.