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"Eggy" Warms-Up

We light-up our lamps of cesium-tritium at the focus of the total reflection parabolas and we see our synthetic crystals scintillating, embroidering with white light cylinders the magnetic hologram already formed. Of course we cannot see the white circles as differentiated but as a surface, apparently spherical, white and transparent, floating in vacuum (we can watch it through the glasses placed among the reflectors), with a shining dot at its center. It is the relative plasma, yet slim, but where matter already exists (the meta-neutron) – and which is constantly growing.

Simmering tourbillons cleaved between matter and pure force twirl at its core; but the massive nucleus has already started vindicating its empire upon energy and brakes the plasma crown’s expansion, helped by the invisible gamma lasers cloud pressure (which keeps feeding the system with energy).

It is here convenient to explain why Eggy’s fatal deflector hologram is not a light hologram in the word common sense but a magnetic hologram: the inevitable interferences between the two coherent field frequencies would compromise the deflector’s efficiency. The emission circuit reflectors are embedded into a spherical armature; this armature generates a magnetic field where we apply the fatal function, so obtaining the needed deflection. Further on I will describe a few interesting facts related to this magnetic field.

We are at the installation phase of Eggy which occurs on the neighborhood of an energetic system able to furnish the millions of GeV needed to form a neutronic nucleus with the desired mass – the spaceship’s mass. Before I risk dismaying the physicians that rule their thought on the quantic field, I must remember them we are dealing with a metadimensional field where the mass-energy relation is compensated. As soon as this mass is obtained, the Eggy become autonomous and the rudder we talked about is operational.

The energy needed to maintain the relative plasma is minimal – we must remember that the plasma is not freely expanding but contained by the metadimensional interface we created: on the exterior limit, it is enough that the laser crown has liminar intensity so as the system keeps in equilibrium. Simultaneously, the metadimensional interface has the effect of grouping the two masses: if the spaceship moves, the neutronic nucleus follows the focus displacement. More: the multidimensional effect communicates itself to the whole structure; the ship floats on the interface (coherent?) and, although its mass remains the same, it is in metaparticular attrition – the minimal conceivable attrition for the material discretization scale of our Universe. Our problem is not to move the Eggy but to keep it still. All the gravitational local vectors must be compensated (happily the gravitic fields are equally diluted by the interface and the absorption index for the cosmic radiation is, for the same reason, extremely high). This compensation is very difficult to modulate as in the situation of almost absolute imponderability where the ship is, any uncontrolled emission of a single particle has the recoil effect of a cannon. Even the communication emissions are made in “duplicate” – an energetic aleocriptic copy is emitted to the inverse axis of the antenna’s flux, so as to compensate the associated inertial effect; and it is the metadimensional interface itself that works as an absorbing shield and slows down all the unpredictable ponderable radiations coming from the interior (the communication band is emitted on the same frequency of the energetic lasers – the only one available if you think a bit about it; and tis, while not a justification, accounts for the understanding of the equifrequential  instability of the laser crown).

About Tritium

Tritium is, as we know, a universal catalyst for fusion. On the other hand, cesium e named in labs slang as the “Heisenberg element” because of its privileged position on the spectral curve rank – it is an alkaline metal, the 55^th element on the Periodic Table: central. On the upper spiral, francium is radioactive. Tritiated-cesium we use is radioactive as well (cesium 137, an abundant element on nuclear waste and an excellent producer of gamma rays which an excellent team of the USA centered in Oak Ridge and Savannah River – see information of TFA Tanks on the Internet, June 1997 – provides purified). The spherical shell which envelops the reactor is coated with crystalline silicontitanide in order to absorb any eventual gamma dispersion, extremely harmful for human tissues. Tritium helps us to modulate the radiation frequency in order to azimuth the universal momentum. FMNL _ Ylab.

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The metadimensional boundary is an auto-similar figure – a fractal – which, geometrically, reversely unfolds from the hypercampic focus as a Pascal lock, following the design of Mandelbrot’s function so well known.

When Einstein wrote the formula for the equilibrium between mass and energy had already completed his reasoning about the light cone. In those days, photon gathered its definition, among other sources, from its quality as material archetype for the discretization of the perceptible. Einstein understood that the universe perceptible archetype had to be coincident with its ontogenesis and its ontogenetic dynamics. Completed the relative orbit, light naturally stood as the harmonic limit for the quantification of the infinite (Heisenberg’s structuralism).

Relativity Theory is a practical tool. It’s cleaving with Newton is merely apparent – Einstein believed until the end it would be possible to solve the physical fields around a completely abridging theory; if nowadays we recognize the impossibility of such an unification (an absolutely unifying theory should contain the equating premises of its gnostic reflex along with its own future, which is absurd (self-deterministic Universe, anthropic fall; we can never escape perspective) it is because our perception field enlarged through the systematic investigation of the quantic world and the physical-mathematical singularities. We dilated our meta-physical field.

A physical singularity happens when the coherent development of its laws unfolds into its own contradiction. That is what happens with black-holes: Einstein himself foresaw their possibility, conscious that the nuclear equilibrium gravitic fall ruined his entropy limit – perhaps with the stoic fatalism of those who understand that you cannot make an omelet without breaking a few eggs. But he always respected the scientific pragmatism limits – and also because of that his theory works and persists. After all, a singularity is an exception and, as so, confirms the rule.

The plain understanding of light is furtive until the moment when we face it with space-time; from then on, the light cone really discretizes, the particle-wave duality becomes obvious and evident, the uncertainty principle become a solid rock base for the quantic building and Plank emerges as the privileged joint venture for Disneyland. Unveiling the secrets of matter is an often arduous tirocinium, but one which directly deals with the structural reflex – an evolutional environment. It is not the light cone that tries to constrain light – it is light itself that, spreading its wave in spacetime, builds the cone. And this, although extremely simple and evident, is fundamental (and often obscured and forgotten). There is no spacetime outside the light cone (just the archetypical ontological matrix) – and the great moustache dives the abyss before the strangeness of a horizon that expands onto the intangible while its structural memory is devoured by the infinite vortex of the singularity… The black-hole is the kind of physical object that definitely redeems theoretic investigation – only this one allows to predict it and encompass the discrepancies that unveil its refuge beyond its shifting dimensional boundary.

Basement

In wave mechanics particles no longer have position and velocity distinct and exactly defined – these characteristics cam not be observed. Instead they get a quantum state that is the sum of their statistical position and velocity. Heisenberg showed that the product of the uncertainty about the particle’s position with the particle’s mass one can never be less than a certain quantity known as Planck’s constant. (Hawking, A Brief History of Time, 85.86).

We cannot describe the behavior of atoms and light inside a very intense gravity field. At the temperature of 10³², Planck’s temperature (10¹⁹ GeV – Planck’s energy, Hawking) the emitted radiation density generates an unmeasured gravity field, preventing us from knowing how the atoms and light behave. This temperature is also named Planck’s wall or wall of ignorance (Reeves, L'heure de s’enivrer: l'univers a-t-il un sens?, 114). The maximum energy we could produce in 1988 was 100 GeV, which corresponds to the weak nuclear force. This is also the energy for the massive vector bosons W⁺, W^- e Z⁰ that carry it, predicted in 1969 by Weinberg and Salam and discovered in 1983 at CERN.

Nuclear matter “freezes” at one thousand million degrees (the exact value for this temperature depends on the global density at the “freezing” point) through a process we denominate primordial nucleosynthesis (Reeves, ibid.). After the initial big-bang, only when the Universe cools down until that point are the matter constituent particles – quarks – discretized and aggregated, forming nucleons (neutrons and protons) which form the atomic nucleus, keeping differentiated according to the exclusion principle.

Structural cohesion is hold by a force, the nuclear strong force, one hundred times more intense than the electromagnetic one (Reeves, ibid. 131). We believe this force is carried by a particle of spin 1, named gluon, which only interacts with itself and with quarks. The strong nuclear force has a curious property named confinement which keeps the particles always arranged in colorless combinations. We cannot have an isolated quark, because it would have color (red, green or blue). A red quark must in spite be linked to a green and a blue one by a “string” of gluons (red + green + blue = white). This triplet forms a proton or a neutron (charge). We can also get pairs quark-antiquark, which constitute unstable particles named mesons. Confinement prevents as well the occurrence of a single gluon, because gluons also have color. We need in spite a bunch of gluons, whose combined colors produce white. This arrangement produces an unstable particle named glueball or stick ball (Hawking, ibid., 107-108).

There is another property of the strong nuclear force named asymptotic freedom, which amounts for a better definition of the concepts of quark and gluon. Around normal energies, the strong nuclear force is really strong and keeps the quarks together. However, experiments with great particle accelerators indicate that for higher energies the strong force becomes much weaker, and quarks and gluons behave almost as free particles. (Hawking, ibid., 107-108).

Here on Earth we don’t have, as so to say, doubts about the nucleus of our atoms defending themselves against death (a life one billion times longer than our Sun’s one). But inside a black-hole they would lose that specific nucleonic characteristic. Gravitational death prevents the conservation of the total number of nucleons in the world (J.G.Taylor, Black Holes: The End of the Universe? (1973), 68).

We know that a star with the mass of our Sun completes its existential cycle successively becoming a white dwarf and a black dwarf. But, if the stellar mass ranges from 1 to 5 the Sun’s one, it precipitates the formation of a neutron star.  (Reeves, ibid., 104). The maximum mass for a stable cold star, above which it may collapse and originate a black-hole, is named Chandrasekhar limit.

Chandrasekhar understood that there is a limit for the repulsion involved by the exclusion principle. Relativity Theory limits the maximum difference for the particles of matter velocity inside the star to the light speed. This means that, when a star becomes dense enough, the repulsion caused by the exclusion principle is inferior to the gravitational attraction. The idea was this: when the star contracts, the particles of matter get very close to each other and so, according to Pauli’s exclusion principle, they must have very different velocities. They move away from each other, making the star to expand. A star can then maintain itself with a constant radius because of the equilibrium between gravity attraction and the repulsion ought to the exclusion principle, just like gravity was previously balanced by heat.

Chandrasekhar calculated that a cold star with more than one time and half the Sun’s mass would not hold against its own gravity (Hawking, ibid). When the repulsion generated by the exclusion principle is nullified by mass, the star collapses upon itself, creating a black-hole. The star seems to over, floating on a region called ergosphere, a petrified events horizon from where nothing, not even light, can escape (~Taylor, ibid., 69).

The critical radius of a dead star, above which all the objects remain retained, is called Schwarzchild radius, a tribute to the physician that discovered it in 1917. Its length for Earth is only one centimeter: if Earth was compressed to the size of one centimeter, nothing would escape from it (Taylor, ibid., 55).

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