Page 205 - Spirit and Mind. Vol 1
P. 205
Nicolai Levashov. Spirit and mind. Vol.1
embryo in utero , whereby the fruit of the maternal flesh and blood leaves the
mother's lap and starts an independent life — just as a star, spawned by a space-
universe, leaves the maternal lap when the impact of its environmental space
decreases its self-dimensionality level.
Once separated from the "parent" universe, the star begins a life of its own — a
span of billions of years — and finally "expires." Indeed, the stars, in their turn, have
abundant time to "give birth" to planetary systems which can support life. Let us
consider the process whereby planetary systems are born. During the compression of
a star, the balance between the radiating surface and radiating volume is disturbed.
This causes primary matters to accumulate inside the star. This accumulation gives
rise to a supernova explosion, causing longitudinal fluctuations of space
dimensionality around the star.
Fig. 4 — A star's outer layers, consisting
of the lightest elements, are ejected by a
supernova explosion into the curvature of
space created by the longitudinal
fluctuations of dimensionality resulting
from the explosion. In these zones of space
curvature, caused by the impact of the
primary matters, an active synthesis of
matter ensues — and the entire spectrum
of the various elements, including the
heavy and super-heavy, is synthesized.
The greater the difference between
the star's self-dimensionality level and
those of the space curvature zones, the
greater the possibility of heavy elements
being born and the more stability they will
have. Depending on initial size, one or
several supernova explosions can occur
during the life span of the star. With each
such explosion, the star's self-
dimensionality level decreases; this leads to a reduced synthesis of light elements and
an increased synthesis of heavy ones. As a result, the density, and consequently, the
impact of a star on its environmental space are increased. If the initial weight of a star
is less than ten solars, at the moment of its extinction it will turn into a neutron star. If
the initial weight exceed ten solars, it ends up as a black hole.
In its qualitative structure, the neutron residue of a star is a very physically
dense substance. This is due to the fact that it is composed mostly of neutrons, which
have no electrical charge and no "empty space" between them, such as exists between
the nuclei of adjacent atoms. Therefore, a star's neutron residue barely deforms its
macrospace enough to create a new linkage zone except with a universe having a
smaller self-dimensionality level, such as an L6.
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