Početna Engleski -

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Everything that exists has always existed in the ether as information,
and in reality as the material manifestation of that information.
Everything that exists has its pair or its opposite, and existence is a process of balancing. The system strives toward balance, but never fully achieves it;
instead, it overshoots and continues to decay and return to the ether.
Sometimes this happens suddenly, and sometimes gradually.

Becoming

When, within the ether which is absolute emptiness a thought of creation arises and a voice as the activation of that thought appears, space-time filled with matter is formed. The energy of that matter is proportional to the speed of its formation,
and its equivalent is its mass. At the same time, at the center of the created space, an anti-space-time, antimatter, or black hole is formed dimensionless, with energy equivalent to the mass of the created space-time filled with matter, but with a negative sign. Together, these two energies amount to nothing absolute emptiness, the ether. Immediately after creation, matter tends to merge with antimatter and return to the state of absolute emptiness. When the created space-time is designed in such a way that its structure resists movement toward the black hole, the system becomes seemingly balanced, but in reality, the time of its disintegration is only prolonged to a greater or lesser extent. The force that strives to draw space-time, or the created matter, into the black hole and return it to the ether is gravity.

Earth

When the particles of the primary rocky material, bound into clusters by frozen water, rush toward the center of the newly formed space-time, they do not move in straight lines; instead, their motion is vortex-like. The potential energy of the rock fragments closest to the center is immense.

When the movement of these fragments, even at the highest possible straight-line speed, performs mechanical work that is far below their potential energy,
they bend their paths and begin to move in vortex patterns.

Two vortices form: a northern and a southern one, with opposite directions of rotation as seen from the center of gravity — from the black hole.
This causes the entire material to rotate and travel toward the center. The axis of rotation passes through the center and is aligned along the north-south direction.

As the fragments approach the center of gravity, they form a material sphere that holds them trapped. Following them come others and still others, gradually forming the Earth as a spherical body composed of rock fragments bound together by frozen water.

There is no heat; the Earth is absolutely cold, rotating under the influence of inertia.
The rocky material remains held together by the force pulling matter toward antimatter, toward their annihilation and return into the ether, which is absolute emptiness. At the same time as the Earth, the Sun and the other planets of the solar system were also formed. The Moon orbits around the Earth, with an angular velocity lower than the Earth’s rotational angular velocity. The Earth tows the Moon, dragging it along then, as now.

Because of this, the movement of the Earth’s surface is not uniform.
If we observe a single point on the Earth’s surface at the equator,
we will find that its speed is at its minimum when it is closest to the Moon,
and at its maximum when it is on the opposite side from the Moon.

Evidence for this can be seen in today’s tides. If we think of the ocean basin as a container filled with water, it becomes clear that when the container accelerates, the water inside rises on the side opposite to the direction of motion, and the water level drops on the side in the direction of motion. When the center of the container (the ocean basin) reaches the opposite position, the Earth’s surface begins to decelerate, and the water shifts in the opposite direction.

A second proof of the acceleration and deceleration of the Earth’s surface could be found through an experiment: If we fix a slender, tall antenna on the Earth’s surface and monitor the movement of its tip, we can assume that if the motion is uniform, the tip of the antenna will not move. However, if the Earth’s surface accelerates and decelerates, the antenna will sway to one side and then the other.

Such a proof exists: it can be found in the published results of measurements of the tip displacement of the Olympic Tower in Munich.
A series of consecutive measurements taken over 24 hours shows that the trajectory of the tower’s tip forms a quasi-circular path, and that after a full rotation of the Earth, the tip returns to the same point. Had the tower been located at the equator, the movement of its tip would have been linear. This means that the elementary volume of rocky material near the Earth’s surface accelerates and decelerates, that is, its momentum changes, implying impulsive loading.

Thus, the elementary volume is subjected to loading and unloading in daily cycles.
In this way, the kinetic energy of the motion of frozen rocky material is converted into the potential energy of its elastic deformation.

However, only a part of the Earth’s rotational kinetic energy is converted into the potential energy of elastic deformation. Due to the internal friction of the material, part of the kinetic energy becomes entropy heat that warms the surface of the originally absolutely cold Earth.

Ice melts and transitions into the liquid state of water, beginning from the surface and moving inward toward the Earth’s interior. At this stage of development, the Earth’s surface becomes covered by a layer of water whose thickness gradually increases.

The rocky fragments, now submerged in water, lose their cohesion.
They transform into water-saturated soil with low strength, relying only on internal friction.

At this stage, the Earth has a solid, frozen core rotating with a constant angular velocity, and a water-saturated soil layer that accelerates and decelerates in daily cycles.

The soil covering the interior undergoes acceleration and deceleration,
and the entire kinetic energy from the changes in its momentum is converted into heat through friction.

As the thickness of the soil layer sliding over the frozen core increases,
its kinetic energy and the amount of generated heat also increase.

When the amount of generated heat becomes sufficient, the unbound rocky material begins to melt — first at the point where the surface layer slides over the core,
then spreading both toward the Earth’s surface and toward its center.

As the rocky material melts, its friction angle decreases, which halts the further thickening of the layer and establishes a stable position of the sliding zone.

Thus, the mantle is formed the molten part of the rocky material and the solidified Earth’s crust, which consists of more refractory rocky fragments bonded together by more easily meltable fragments, in a process resembling modern metal-ceramic technology.

Thus, at this stage, we have an absolutely cold Earth’s core and a solidified crust covered by water, with a mantle of molten rocky material lying between them.

The Earth’s rotational kinetic energy is partially consumed for its heating.
This energy is replenished in the following way:

The place where matter and antimatter were generated from the ether
is the place where all the antimatter or its energy equivalent is concentrated.
This place is unimaginably small and possesses unimaginably high inertia.
It is located at the center of the Earth’s sphere and is surrounded by a small number (a few) of material particles.

These material particles, located immediately next to the antimatter (the black hole),
descend into it and return to the ether (absolute emptiness).
The removal of these particles causes a disequilibrium and induces a compression wave (pulse) with a negative sign, or a tensile wave (pulse).

This results in the displacement of all other particles in sequence. Due to the enormous difference in potential, the trajectory of particle displacement takes on a spiral form, forming a vortex wave (pulse).

The movement (displacement) of particles has two components:
a radial component toward the center, and a tangential component, which is aligned with the initial rotation. The tangential component is also tilted relative to the ecliptic.
It can be further decomposed into a component parallel to the ecliptic
and a component perpendicular to the ecliptic that is, parallel to the rotation axis.

The tangential component parallel to the ecliptic imparts to each particle an impulse that supports rotation. The component parallel to the rotation axis draws all particles of the Earth toward the equator. This results in the evident flattening of the Earth.

The flattening index is an indicator of the consumption of Earth’s material,
which reveals the Earth’s age.

The radial component is gravity, which is also a wave (a pulse without reverse motion).

The Earth, in its motion, consumes its mass, which gradually decreases, while maintaining constant rotation. Both matter and antimatter are consumed, thereby maintaining a constant difference in potentials.

The Earth’s core rotates at a constant speed, while the Earth’s crust, due to gravitational interaction with the Moon and the other planets of the solar system,
accelerates and decelerates.

Between the core and the crust lies the mantle, which functions as a friction clutch.
The mantle is, quite literally, the athanor of an alchemical laboratory.
Within it, under high pressure and high temperature, the transmutations of the initial rocky material take place.

Water is decomposed into hydrogen and oxygen, and then, like a hydrogen fuel cell, it generates electricity, which in turn forms the Earth’s magnetic field.

When an unknown planet, with a strong gravitational interaction, passed near the Earth which at that time had a flat, relatively monolithic crust covered with water
a radical reshaping of the Earth’s surface occurred.

Thanks to the friction clutch of the mantle, the core was protected from the strong newly induced torque.

The crust, in the pressure zone in front of the segment experiencing the strongest gravitational interaction, was fractured, leading to thrusting and the formation of mountain ranges, with their orientation perpendicular to the direction of the maximum principal stresses in the crust.

Behind this zone, the crust was subjected to tensile stresses, leading to the formation of large fractures of the same orientation.

After the passage of the activating planet, water accumulated in the lower areas, while higher areas became land.

Judging by marine fossils found at the tops of mountain ranges, this has happened multiple times and will happen again.

The Earth’s crust at the poles and in their vicinity, due to lower velocity and a shorter traveled path, possesses less kinetic energy, thus performing less frictional work and producing less heat.

For this reason, the poles and their surrounding regions remain frozen.

In addition to the Moon, the Earth’s crustal rotation dynamics are also influenced by the gravitational effects of the other planets.

When the Earth, the Moon, and another planet align „in line,“
the gravitational influences of the Moon and that planet combine.
Their intensities add up because both the Moon and the planet rotate more slowly,
thus exerting a braking effect on that part of the Earth’s crust.

Situations where multiple planets are aligned are rarer, but the resulting influence is stronger.

When analyzing the influence of a single planet whose ecliptic deviates significantly from the Earth’s ecliptic, the vector of that planet’s influence is not colinear with that of the Moon, and therefore their resultant is not colinear either.

The force of the planet’s influence can be decomposed into two components:
the first lying in the plane of the ecliptic, and the second perpendicular to it.

This means that the Earth’s crust slides over the core not only in the direction opposite to the core’s rotation, but also along the north-south direction.

As a result, the magnetic pole which is fixed and aligned with the rotation axis of the core does not coincide with the geographic pole through which the Earth’s crust rotation axis passes.

Naturally, as measurements confirm, the Earth’s crustal rotation axis constantly shifts.

The rotation axis of the Earth’s crust drifts away from the rotation axis of the core
and moves toward the zone where the mantle beneath that part of the crust is increasingly heated.

Consequently, ice on that part of the Earth’s surface melts more intensively,
while on the opposite side of the crust, ice formation becomes more intense.

And this has been happening constantly, and since always.

Earthquake

The Earth’s crust is under stress. This stress is not constant, and it is caused by two phenomena.

The first is gravity, whose intensity does not change, since the potential difference between matter and antimatter remains constant.

The second active principle, and the cause of horizontal stresses in the Earth’s crust,
is the deceleration of the Earth’s crust in the zone of gravitational interaction with the Moon and other planets.

Consequently, the Earth’s crust undergoes cycles of loading and unloading.
There are also zones subjected to tensile stresses otherwise, what would create fractures on its surface, as still occur today?

There is no „pumping“ or accumulation of earthquake energy.
There is only a change in the intensity of loading and unloading.

The greater the gravitational influence of the planets, the greater the intensity of the change.

When the change in intensity is sufficient to cause significant displacement of tectonic plates along faults,
a compressive (seismic) wave is induced,
which manifests at the Earth’s surface as an earthquake.

If for a historical seismic event at a specific location, for which the exact time is known,
we determine the arrangement of the planets at that moment,
then in every future situation where the geometrical positions of the seismic event location and the planets that exert significant gravitational interaction coincide,
we can expect a similar seismic event on Earth’s surface.

There are no coincidences, and no singular events everything is a cycle.

Climate Change

The increased gravitational influence of other planets on Earth depending on their spatial configuration causes greater deformation work within the Earth’s crust. More work implies higher entropy and increased heating of the crust. This is supported by numerous published reports from glaciologists: glaciers do not melt on sun-exposed surfaces, but rather at the interface with the underlying bedrock. Intensified heating of the Earth’s crust occurs beneath oceans as well as under high mountains. Glaciers are not melting because of climate change; rather, climate change occurs as a consequence of glacier melting. In addition to increased crustal heating, stronger gravitational influence from other planets leads to greater shifts in stress fields, which in turn causes more frequent and intense earthquakes.

The Sun

Just as the Earth was formed, so was the Sun only on a much, much larger scale. Due to the strong gravitational influence of all the planets that the Sun pulls along, and the immense heat generated by friction, the Sun began to melt starting immediately from the surface and halting at a certain depth. The Sun’s molten structural material, likely in a plasma state, probably has not only no internal friction but is also characterized by low viscosity. The solar core maintains constant rotation, just like the Earth. And the Sun, too, has its own crust and a friction clutch between the core and the crust. The gravitational influence of the planets acts upon the solid mass of the Sun’s crust, not upon the plasma at its surface. The crust accelerates or decelerates depending on the arrangement of the planets. The plasma at the Sun’s surface behaves like water on the Earth’s surface: while the crust slows down, the plasma, like ocean water without shores, continues moving forward more so at the equator, less at the poles. Just as with the Earth, the Sun is more heated at the equator than at the poles. Every 11 years, when several planets group together and jointly decelerate the Sun’s crust, a pronounced jolt of the crust occurs, causing a more pronounced forward surge of the plasma. At the site of maximum jolt, the plasma reveals the Sun’s crust beneath the ocean of plasma which is less heated and this manifests as a sunspot.