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.


Self Assembling Lyotropic Aether

Created with GIMP

So light propagation, in my view of the universe, happens via self-assembling lyotropic aether. Anything that is lyotropic is defined as something that can dissolve and reform. Lyotropic aether forms in the presence of energy, and dissolves in the absence of it. When the aether is dissolved, the energy is scalar energy. When the aether is structured, the propagation has a vector. The emanations of momentum from an atomic orb are instantaneously scalar, but within the almost non-existent percolation time of an aether level “plank” unit – becomes vectorized by the self assembly of the aether.

Throw a pebble into a pond, and watch the ripples form.  Does the “wave” have a direction?  No, it emanates in all directions.  Thus, we might consider the ripple to be scalar energy, at least on a two dimensional level.  So it is with atoms.  For an instant, the energy emanates as the energy of the pebble wave, but just as instantaneously, that wave is vectorized into rays propagating through self-assembling lyotropic aether.

A special type of crystallography defines the aether’s lyotropic nature. It is an extension of the crystallography that defines all of chemistry.  An example of a lyotropic crystal that behaves exactly according to current physical chemistry precepts is the LCD crystal of a monitor screen or television.  LCD crystals become structured in the presence of energy, and unstructured (or other structured) in the absence of it.  So, extending the concept of the crystal we are familiar with (LCD) – we better grasp how the lyotropic aether version may work.

So, inherent in my thinking, the observant reader would know, is that I do not consider the “photon” to be the elemental unit of energy. Obviously, for an atom to emanate energy in a scalar manner, subsequently instantaneously vectorized, means the elemental unit of energy is smaller than the conventional photon.  The true elemental unit of energy is related to the effective “plank” unit for aether, and not the conventional one.

The vectorization of lyotropic aether causes a medium discontinuity, or boundary condition.  Transverse waves are known to form along a boundary condition or gradient in mediums.  The ocean wave is an example.  So, primary light propagation is longitudinal scalar, instantaneously vectorized, and followed by a secondary wave following the boundary condition and helped along by refraction within the crystallography nature of the lyotropic aether.

Understanding that crystallography defines the universe, all its components, and all of the so-called “space” in between them, we can extrapolate geometric precepts to discover more about physical chemistry.  If the crystallographic nature is seen at all levels (aether/atomic/molecular) – then it seems to paint a different picture for the atom than what we’ve been accustomed to believe.  The atom, on geometric terms, seems to be implied as a type of Goldberg tetrahedron.  Special types of Goldberg tetrahedron seem to align nicely with valence electron counts in atoms, and do not need all the “special cases” to explain the interactions as conventional chemistry does.


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.

Light Creates/Grows Latticework as it Propagates

Light grows latticework in the direction of its propagation, via its percolation, and then its refraction. When entanglement is involved, light creates a superlattice in the direction of propagation. This latticework is the result of the action of the percolation of light through lyotropic aether, as opposed to the subsequently refracted transverse light energies.

This is a better way to describe two phase or two mode light, than the way I have used in the past.  I’ve been describing two-factor light as a self aligning, self propagating effect, akin to the lyotropic crystal alignment that happens in LCD monitors.  But – it’s more than just an alignment – it’s literally the creation of a lattice framework in a way analogous to the well known elemental crystallography associated with physical chemistry.  It’s just that it happens in lyotropic aether as opposed to normal matter.

The magic angle of 1.1 degrees misalignment is what creates superlattices in the types of crystals used for generating entangled photons. The same 1.1 degree angle creates a superlattice in graphene, which subsequently leads to paramagnetism effects and to superconductance. So, light in transit is not necessarily a superlattice creator, but causes only lattice alignments when the magic angle is not involved.

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


The Universe is not Holographic, but it Creates …

The universe is not holographic, but it creates a hologram from its reality. I’ve always had a problem with Bohm’s holographic universe because the hologram needed a reality source. The hologram is a flattened interference projection onto two dimensions. But it is an interference pattern of real objects in a real world. So, the holographic universe made not much sense. However, the universe is indeed full of interference, and so a snapshot of that interference pattern, flattened, is a hologram. The universe creates a holographic source with its reality. In terms of reality and real objects, that doesn’t say much. But in terms of the interactions of objects, it may say quite a lot.

One can say that the objects themselves constitute a sum of interference, and thus can be holographically interpreted.  While true, the holography is a map of the interference of energy, not the energy itself.  So, the universe is not holographic in origin, but only in the resulting patterns of connections and interactions that materialize from real energy in a field of aether defined by crystallography.

Reality is a conformation of energy in the aether, and the hologram projection of that reality describes the interations of one part of the reality with another. So, reality is the source for a holographic interpretation of the universe, of its interelated parts.

The hologram shows us the connections of the reality in the universe. Those connections may influence adjoining pieces of reality in a large or a small way. The transverse wave holograph relates to connections with the least influence.  The incoherent, non-entangled quantum hologram relates to connections that have more influence than the small transverse wave influences, but less than the quantum coherent, percolated entangled energy moments that have the biggest influence.  Three different holographic representations are created.  The first is the refracted transverse wave hologram.  It is limited by the geometric resolution of the wavelengths of the transverse wave, and by the Nyquist limit.  The other two holograms are quantum holograms, which have no Nyquist limit, and infinitesimally small geometric resolutions.  They are vastly superior.  

Why are they superior?  Because they lack the overlapping patterns in the T-wave hologram.  How could they lack the overlapping patterns?  They lack the overlaps because quantum percolation filaments keep their integrity even in fields of interference.  This allows for the “teasing out” of the tiniest variations of interference in the quantum holographic representation, where the transverse wave hologram would reach its resolution limit before it was useful for many things.  With one of the quantum hologram types, it might be possible to tease out the state of things anywhere in the universe with only a small sample of the universe.  It would be a looking glass truly deserving of the name.

The human brain might be able to “tease out” certain things in either type of quantum hologram, based only upon the small geometric volume the brain contains.  I don’t think the transverse wave hologram is viable for the brain, but perhaps one of the quantum modes could be the basis for remote viewing, and ESP.  I think it’s likely that the incoherent, non-entangled quantum percolations are a weaker field by virtue of the scattering they suffer, such that they represent lesser potential for both brain connections and for generalized quantum communication channels.  The filaments of such aether pathways are not bunched. The best potential for quantum communication is direct aether filament percolation and the associated “full entanglement” of reflexive “Wilburforce Pendulum” style echoes.  The power of the coherent, entangled class of connection is mostly the result of energy that is directed within aether filaments and which possess sufficient bunching to effect complete cycles of echoes.

How could a hologram of the quantum variety be recorded?  I envision a nearly perfect sphere of graphene mesh might be what could be used, or a dome of the same material, as it seemingly would record the fullest impression of the full interference map of quantum percolations.

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.