Today, astronomy has no understanding of how globular clusters formed and why they continue to exist at present time, while maintaining their configuration.
Some properties of globular clusters:
1. The structure of globular star clusters is stable. Moreover, it is invariable. The stars that make up the cluster are motionless. They are motionless relative to each other, and the cluster itself is also static.
2. There is No dust in globular clusters
3. The distribution of clusters around galaxies is almost spherical.
Being on the positions of the official doctrine, it is impossible to comprehend what prevents the gravitational collapse of these conglomerates, but the official science is trying to get out of the situation by assigning to the globular clusters giant size.
For the beginning the note, that for a better understanding of this section, you must first familiarize yourself with the theory of the structure of substance from the standpoint of the Law of Mechanics.
Here we just mention that the Law of Mechanics proposes that there is a special form of matter – a monolithic ether.
In contrast to the usual substance, which is permeable to the gaseous ether, monolithic ether is impermeable, since inside it there are no gaps or voids through which the gaseous ether could seep.
Consequently, the movement of macroscopic bodies consisting of a monolithic ether requires a displacement of a large volume of gaseous ether. For sufficiently large bodies of monolithic ether motion relative to the ether is almost impossible.
In other words, the monolithic ether has a mass close to infinity, and its acceleration in the ether requires forces tending to infinity. This almost infinite inertia of the monolithic ether leads to the circumstance that the bodies consisting of the monolith ether cannot move through the gaseous ether and always move with the gaseous ether.
In general, the topic of monolithic ether requires special consideration. This is a completely new, yet hypothetical state of matter, the existence of which is predicted by the Law of Mechanics. As far as I know, the very possibility for substance to be in a state similar to monolithic and be impervious to ether has not been previously considered. The properties of such substances must be quite extraordinary.
Imagine that such a substance was on the surface of the Earth. It is likely that gravity will push it down to the planet’s core. To keep the body formed from such a substance on the surface will be possible only if it is possible to resist the pressure of the ether moving in the direction of the center of the Earth. The smaller the transverse dimensions of the body, the less resistance it should have to the gravitational flow of the ether. What is the total pressure of the ether is not yet clear; it is also unclear whether the ether can flow around macroscopic obstacles, if it is not possible to seep through them.
It is possible that the very core of large celestial bodies with gravity, consist of an ethereal monolith. Star cores – most likely. The hypothesis of the ethereal monolith allows us to give unforeseen by simplicity and obviousness explanations for many puzzles and unsolvable questions observed both in remote places of the universe and very close. But more about that sometimes later.
In the meantime, back to the globular clusters.
Although the existence of the ethereal monolith is questionable, there are indications of the reality of the presence of such a state of matter, and one of them is the globular clusters and their evolution into open clusters. It is possible that there is some other explanation for the properties of globular clusters, also satisfying all the observed facts. But so far only the monolithic state of the ether in combination with the Law of Mechanics able to cope with the explanation of the properties of spherical clusters.
The photo shows a globular cluster Messier 13 (NGC 6205).
Description of the process of formation and development of globular clusters in accordance with the Law of Mechanics.
Globular clusters were formed as an outcome of the collapse of large stars due to the pressure drop of the surrounding ether to a critically low level. The arising pressure wave of the released ether causes the decay of smaller celestial bodies by the domino effect.
The process of decay is somewhat similar to the hypothesis of the disintegration of the planet, the pieces of which presumably formed a belt of asteroids.
Here again we return to the idea of how fragile is the balance on which the planets, stars and the substance as a whole are built. Everything is held by external pressure, and in case of its weakening, or a sharp change, the structure of the planet or atom or proton may disintegrate.
For the planet it is enough to get between two oppositely directed flows/vortices of ether, to experience the bursting effect of the ether. Planets having the misfortune to be in these conditions risk being torn to pieces. Apparently the size of the planet should play a role in determining the fate of such a planet, because the own gravity of a large planet will keep it intact. In this case, we can have a planet escaped from the galactic plane and joined the galactic halo.
All of these scenarios may be related to the fragmentation of superstars as a result of the depletion of the ether, and the presence of a large number of globular clusters inside the nebulae may indicate just such a process. Under certain conditions, the nucleus of the galaxy disintegrates, sending a shock wave in all directions from itself; this shock wave of the ether can be the cause of the breakdown of many stars and planets included in this system. As a result, we will have a nucleus-free galaxy containing a large number of globular clusters in a cloud of dust, something similar to the Large and Small Magellanic Cloud, and possibly the Milky Way Galaxy.
The described scenario allows to explain the observed properties of globular clusters.
Composition: almost free of heavy elements, almost pure hydrogen and helium. This may be the result:
1) The initial total decay of material bodies smaller than a few kilometres, that is, the guaranteed decay of complex gases and dust. As a result, the globular clusters contain almost no heavy elements, and only hydrogen and helium remain.
2) Slow evaporation of the monolithic ether of which the large fragments consist. As a result of this evaporation, free gaseous ether and protons are formed. The free ether slowly emanating as a result of evaporation causes a gradual expansion of globular clusters and thus the evolution of close globular clusters into open clusters.
3) Fragments of the ethereal monolith pass through the process of grinding the protruding parts, and turning into balls. This is one of the processes leading to the formation of spherical shapes in celestial bodies. (Other processes leading to the same result — the formation of spherical shapes in celestial bodies will be considered in the relevant sections.)
Now about the possibility of rotation of fragments of the superstar, which consist of monolithic ether. It is obvious that the linear motion of large blocks of monolithic ether relative to the gaseous ether is impossible due to the impermeability of the monolithic ether. But the rotational motion of a spherical body does not require crossing the ether (penetration through the ether). Globe of monolithic ether, displaced the gaseous ether, has the ability to rotate without experiencing significant decelerating and centrifugal forces.
Decelerating will depend on the degree of roughness of the surface, and how it differs from the ideal ball. Perhaps this imperfection in combination with roughness can explain the red or yellow glow of some objects in globular clusters. These objects have rotation unlike their white neighbors, which only reflect light.
A very interesting property of bodies consisting of a monolithic ether should be the absence of centrifugal forces. As a result, you can have almost unlimited rotational speed…
Fragments consisting of a monolithic ether can possibly glow without rotation, simply evaporation of the monolith into hydrogen and the transformation of deeper layers into some heavy elements. It is possible that both of these processes are accompanied by the release of light. That is, there may be another process of illumination of stars, in addition to gravitational.
Unlike gravity, the process of evaporation (melting/sublimation) of the monolithic ether has a limitation on resources; the process can only continue until the monolith is used up. I.e. internal reserves, limit the process duration, the influence of the external pressure of the ether is less important. In contrary to Gravity, which uses external reserves of ether, which are almost unlimited.
The shape of globular clusters repeats the shape of the ethereal “bubble”, which is formed when the ether is released during the decay of stars and planets. We can say that the substance suddenly converts into space (monolithic ether transforms into gaseous). The emerged space is expanding carrying the fragments of the monolithic ether. Having expanded up to the pressure of the surrounding ether, the newly released gaseous ether stops, and with it all the bodies consisting of the ether-monolith stop.
Further expansion of the globular cluster is very slow. And since the “stars” of the monolithic ether do not have gravity, no movement within the globular clusters does occur, except for the only available method of movement — rotation.
Accordingly, the distribution of globular clusters is also spherical, since it is subject to the motion of the ether released from the nuclei of “galaxies”.
The Law of Mechanics 