The basic stages in the Earth's pre-geological development

ї Trunaev E.M.

Part 2

The Basic Stages in Earth's Pre-geological Development
( as well as that of the Sun, planets and their satellites).

Scientific research has uncovered facts at odds with ideas about the structure and evolution of the solar system. The giant planets and their spherical satellites exhibit unexpectedly high thermal activity, though they used to be considered a mix of gas, ice dust or pieces of ice. It appeared that the surface of the majority of the satellites was a firm crust beyond the molten stage, though having obvious attributes of active volcanoes in the past or present. The chemical composition of all these satellites was found to have unusual variety and to highly differentiated, showing the existence of heavy chemical elements of the ferric and other groups, even the in small satellites of the giant planets. However, the real sensation was the detection of magnetic fields, or attributes of residual magnetization, in the mountain rock of all the planets in the Solar System, and the presence of magnetic dipoles on many satellites of the giant planets. A firm basis in natural science attests to these facts; they cannot be understood or explained by traditional cosmogenic theory.

The following explanation seeks to resolve these and other essential, important questions of natural science.

After fragments of the Vortex sleeves separated, whirlwinds of second and third orders ("NC" - new micro-vortex) were generated- future planet cores and their satellites - all of them developing independently, governed by the common laws of development of cosmogenic vortexes. As neutral gas proceeds to the center, the concentration of particles in each whirlwind increases, and the circulatory speed grows exponentially, in some parts of the spiral reaching 650 km/sec. The energy of particles moving at 650 km/sec is equivalent to a temperature of 10⁸ degrees Kelvin. With such kinetic energy (kinetic temperature) electrons are broken off of their orbits in atoms, and gaseous matter gradually passes into a plasmic state. The plasma is in cosmogenic vortex of alternating layers of protons and electrons, providing it with a so-called quasineutrality.

The ordered spiral, circular movement of charged particles (electrons and protons) in a whirlwind represents a spiral electric current, which by analogy to a current in a cylindrical coil, results in a total electromagnetic field for the vortex (magnetic dipole). Let us label the following parts of the dipole thusly: an internal 'trunk', around which the whole vortex rotates; two poles - northern and southern -- defining the end limits of the 'trunk; and an external spherical part, beginning at the poles and in regular intervals covering the central 'trunk' part of the dipole like a cloak of sorts.[see fig. 3-a].

From the moment of the dipole's inception, the charges, being in the vortex, will be compelled to conform to their 'own' magnetic field and to the laws of magnetohydrodynamics. In particular, all charges driven by the spiral to the center of the vortex will now also have to move axially along the lines of the magnetic dipole's power. The dipole's lines are elastic, enabling the charged particles, as their own sort of 'directing rails', to form a spherical skeleton, made wholly of rather elastic magnetic power lines. Thus, there is an axial movement of the vortex's core mass, promoting part of the matter to be expelled ('pumped') from the vortex core to the magnetic dipole's spherical covering, leading to subsequent movement in the sphere from one pole to another.A spherical magneto-ion mantle has thus gradually begun to form, surrounding a rarther flat vortex. Owing to the influence of the magnetic field, the matter in this 'cloak' flows between poles along its own interpolar, closed magnetic power loops. Furthermore, the magnetic dipole's power lines enable the newly-formed cloak to assume a pulse of rotation along its entire width from the quickly-rotating vortex located inside it. This essentially defines the character of the radial and latitudinal differentiation of mass rotation of weights in the top layers of gaseous (plasmic) celestial objects (e.g., today's giant planets or the Sun). The above example can illuminate the basic nature of yet another natural phenomenon, as yet not explained by science.

In the formation of the magneto-ionic mantle, each 'NC' (including our star, the Sun) has a preliminary stage of formation, starting as rather flat, quickly rotating objects in slowly rotating spheroids. A certain amount of matter becomes isolated in the cneter of every vortex through the interaction of the dipole's 'trunk' power lines and their particles of rotating plasma. This matter assumes the form, properties, and functional capabilities of an adiabatic pseudo-speherical (negative curvature), open, magnetic snare (bottle). [see fig. 3-a].

Snares of this type stabilize plasma, isolating it from the external environment's adverse influence, protecting a plasma body from disintegration and promoting its normal development. According to the law of preservation of magnetic and rotary moment, there is further acceleration in the rotating-screw (axial) movement of particles [see fig. 3-a, b] in the core of the magnetic bottle. As this happens in the area near the southern end, where particles stream out as if a 'stopper' of sorts has been pulled, the possibility of particles colliding is greatly increased.

Upon colliding, the separate particles lose some energy in their circular movement (kinetic temperature) and become 'unstuck' from the magnetic power lines. They move beyond the limits of the magnetic snare through the southern magnetic 'stopper'. Here each proton grasps one electron and, thus, we get atoms of hydrogen 'of the second generation', formed directly from plasma. However, when the energy of breaking particles exceeds their electrostatic repulsive force (Coulomb barrier), they will merge. During the so-called proton-oroton cycle, high-energy particles will alternately break and reform, thereby leading to the creation of more complex and heavy elements. In the core of each spherical celestial object of the Solar System, at a certain stage of itsevolution, conditions exist which promote evolution, the nuclei of elements undergoing exothermica processes of synthesis (thermonuclear synthesis). The atoms of all elements, which now form the outer layer of various celestial objects (the Sun, planets, their satellites), were formed from plasma. This explains the core of celestial bodies having attributes of former thermal activity - in contradistinction to that observable today -- as well as a surprising variety in structure and composition.

More complicated chemical structures continued to develop inside the Solar System, right up to the plasma's complete disintegration and the disappearance of the magnetic field's dipole. (This has happened with Mercury and the Moon.)

It is known that about 1/3 of Earth's total weight is concentrated in a small, very dense core, which is essentially the remains of the original hydrogen, formed through the differentially rotating plasma. About 2/3 of the mantle's weight consists of matter "pumped" from the core, thereby giving it a variegated structure. Our planet's core today is comprised of considerably deteriorated cosmogenic vortex; consequently, the Earth has a moderated magnetic field. The majority of the planet's matter consists of plasma, hard rock, liquid, and gas, which are located, respectively, in the mantle, the crust, the hydrosphere, and the atmosphere.

Some planets still have plasma (in their core), serving as the raw material for the construction of new elements or matter. (Some of this 'building-block' material is hydrogen and helium, often called 'relics'.) Second-generation hydrogen flows up through fractures to the top of the mantle, then the crust, and finally the atmosphere, bonding with oxygen and ozone to form water. This clarifies how so-called "ozone holes " are formed over deep fractures, especially over the Earth's southern region (East Antarctica, [see fig. 3-b], where hydrogen is quite abundant.

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