aliens

Everything can't be wrong. Matter changes into different non-biological materials as it comes out of the planet and biological material seeps into the planet. Over a long period of time. What did the first particle of matter come from? I was looking for the possibility of the particle of matter coming out before the big bang. Assuming that before the x mass of matter accumulated, there was dark matter or empty space in the universe, on which it accumulated. I didn't talk about the time of the universe or the order of the formation of matter, which is described as the cooling of dense mass and the expansion of space. Dense mass, x-bosons quarks, antiquarks, quark plasma, hadrons, protons, neutrons, antiparticles, neutrinos and, in parallel with the latter, leptons, electrons, positrons. Subsequently, deuterium, helium, lithium and beryllium atoms formed by the fusion of protons and neutrons. The first stars were made of this matter. It is not known what squeezed all the matter together up to the x-boson and the cooling and expansion are well described. It's possible that the decay of matter can be repeated in reverse. The idea was this. Where did the first particle of this dense mass begin? Before space compressed its staff.

nice reading material :)

Having delved a little deeper into the topic, the answers are here. How Spin arose and Electromagnetic radiation, mass and electric charge began. There were a few stumbles in the previous texts. But Ruut wanted to know so much and the wire was not satisfied. So I went to investigate the matter. Spin is an interesting phenomenon. It is the rotation of some kind of particle. At first glance, it seems that it does not have a deep meaning, but it does. Very deep. The galaxy rotates. Apparently the universe rotates too. The rotation of the Earth. The change of seasons. or changing the side relative to the sun to maintain existence and not become a desert. Therefore, the basis of life. Very necessary now. Let's move back in time, to the beginning. From there, we can figure out why spin arose. Proton, half a spin, a combination of three quarks, which developed further. (two lighter and one heavier quark) the mass of the remaining quarks is at least 10 times greater. Hadrons, are a combination of three quarks, which did not develop further. Probably due to the large mass of quarks. But the holders of the initial material of matter mass. Quark, half spin, 6 special types. Gluon with mass and charge difference is the glue of quarks. Carry color charges (you can say that the protective layer of quarks) 8 special types. Quark bosons, absorb and leave quarks z-bosons spin 1 mass and Rotation carriers. . w-boson spin one (key particle) Because it is the first carrier of radiant energy and mass and positive charge, between quarks. (The focus is then on the positive charge). A negatively charged boson transporter, between quarks has not been described. Thus, positive motion is preferred. Negative is the electron. electron half spin. moves at 75% of the speed of light. Combines with particles and is not absorbed. negative charge. Neutrinos, three types, spin half, extremely small mass, only left-handed rotation and motion. good candidate for the electron, with its left-handedness, in the negative direction. There are no positive ones. Speed of light. The only mass that moves at the speed of light. photon 1 spin, the carrier of electromagnetic radiation energy moves at the speed of light. Absorbed in all particles and also leaves there. From this list, we can conclude that spin is vital for all of them. In order to preserve radiation, energy or mass as a separate entity. So how did spin and photon and energy begin. First of all, emptiness. The property of emptiness is to increase, to become a larger emptiness. (the emergence of space) In order to describe emptiness and for emptiness to exist at all. you must imagine another emptiness in this emptiness. One of these emptinesses is a denser emptiness. They cannot be similar because they are immeasurably large. So since the other is a denser emptiness, an interaction took place in this emptiness. The density in this emptiness began to concentrate. Becoming a representative of density in relation to both emptinesses, i.e. the opposite of emptiness (energy). Therefore, it has the property of concentrating. Such concentration could have taken an insane amount of time. Considering how big the void is. However, since matter did not exist, time did not exist either. In order for something to concentrate, a means of transport is needed. Energy had to want to concentrate. This something was a particle of the density of a denser void, i.e. an energy particle. Energy is radiation. Radiation is movement. How could energy start moving? Due to the urgent desire of energy, one part of the energy made half a turn around itself! A circle was formed. With the formation of the circle, a virtual shell (pin tension) was formed, between the sparse and denser medium, between energy and emptiness. From that moment on, a more advanced interaction was created, as well as the ability of the denser medium to maintain its shape and movement. Photon. This is how the emergence of the first spin and photon, i.e. radiation, i.e. movement, i.e. a virtual shell, between Energy and emptiness could be described. Energy was forever created to radiate, accumulate, move, absorb, wave, heat up. The emergence of the existence of spin polarized the photon, i.e. gave it a preferred direction. Many photons were created in the void and possibly by meeting and passing through each other, more were created. Apparently, the accumulation of energy had its own density limits. The entire void of photons gathered together. All photons moved at the speed of light and rotated (when a certain density was reached, such a bustle probably creates a lot of thermal friction). The energy mass was enormous and hot. The structure needed to change in the ever-increasing heat. A photon star was created. The size of this star was assumed to be 380,000 light years. With an extremely hot content. A core formed inside the star. Due to the extremely high density in the core of the star, the photons could no longer fit next to each other or move at the speed of light and, passing through each other, merged into neutrinos and, inside the core, perhaps a Higgins bositron, but considering the uniqueness of the process, they finally merged into something that would definitely remain in the center of the core. An electron. The electron could never be destroyed again, because it is the smallest particle with mass. Who knows how many photon mergers were needed to create a neutrino and then an electron. With the merger, other photons and neutrinos entered the space. As a logical conclusion, mass was created in this photon star. In the form of an electron and a new form of energy. Since it was a photon star, the electron acquired part of the photon's spin and speed (in the form of slowed motion in the heart of the star) and also magnetic properties and charge, since it had spin, representing the star's core. This is not difficult to imagine, because an electron differs from a photon only in half its spin, small mass, charge and 25% of its speed. Subsequently, many electrons were created and a huge number of photons were created, which merged with them and excited them, under extremely high pressure. Electrons and neutrinos were created until their mass was estimated to be 146.2 light years. e. 26% of the entire photon star. With the formation of mass, the star turned into an electron star and with the emergence of gravity, the star's core was formed. Under the enormous gravitational pressure of the nucleus formed by electrons, six different types of quarks and guanines were formed, i.e. they were the magma of the electron star. Assuming that the size of the electron star was 146.2 light years, then there was a very large gravitational force in the center of the star, in which electrons merged into quarks. Probably 4-40,000 electrons merged into one quark. referring to the different masses of quarks, from the edge of the nucleus to the center of the star. At the same time, they could also be neutrinos, but the mass of the electron is larger and was probably closer to the nucleus. The first positive charge appeared in the form of quarks. i.e. the opposite of the electron. Let's assume that a positive quark was formed by an even number of electrons. The exchange of mass, charge and spin between quarks took place via z and w bosons. A new particle of matter was created forever. The quark formed a strong shell for itself and it is so small that only w and z bositrons can pass through the shell. Quarks formed clusters, and one of the most successful was the cluster with the smallest mass. The combination of 2u and 1d. Apparently from the extreme areas of the electron star's quark core. When the u and d quarks were formed, the quarks merged into a proton, while the rest merged into different compounds but did not develop further. The formation of the proton was a breakthrough moment for the star, because the proton also managed to lock itself forever in its shell, through the nuclear process. Spin is also important here. The atomic nucleus was formed from protons. Creating the first atom of matter. This nuclear process is assumed to have released a lot of energy, and when 19.5% of the star's mass turned into atoms, the electron star exploded. It also exploded because the first substances that were formed were gases, hydrogen, helium, lithium beryllium, which was surrounded by an electron coating, i.e. electricity, at least 35 light years thick. Thus, a whole universe full of gas, inside the electron star. Around the nucleus of quarks. was like a double-whammy explosion. From that moment on, time began and matter had already been created. The scattered gas and electrons began to merge, and the first gaseous stars were formed from matter, and the chain of creation of new substances could have begun. Several more atomic syntheses and explosions occurred until iron stars, and probably planets. Maybe it is not very important whether there was another particle with mass between electrons and neutrinos, photons, but it would be interesting to know. It has not been preserved so far and if there is, it is inside dark matter. 19-19.5% of the mass of the electron star turned into atoms because 4.4% of the entire universe is matter. Less than one percent were electrons. which remained in the composition of matter. The remaining 80% of the star is dark matter. e. 22% of the entire universe. 380,000 light years because I reduced the universe by 13.7 trillion light years at the speed of light. To the time after the Big Bang. The size of the electron star was 146.2 light years, because this size was the size of the mass of matter in percentage, i.e. 26% of 380,000 st. light years. An electron shell of 35 light years could cover the core of an electron star. A photon star can never be formed again, because there is not enough emptiness for the accumulation of radiation. Gaseous and electron stars cannot be formed either, but similar events could have occurred in the third emptiness. The star may have seemed large, but the material was also very light at the beginning. Knowing this system, one can imagine how many times one would have to bombard one photon, with a photon, in a dense mass of photons, to get a neutrino, and how many times, under even greater pressure, one would have to bombard one neutrino with neutrinos and photons, to get a bositron or electron from it. But it is known that 600 electrons would have to be compressed, melted and bombarded, with photons and neutrinos under even greater pressure and heat, to get a quark. All of them are very well hardened and practically unbreakable. We do not see the explosion of a photon star because the matter of the Earth was an electron-sized part of this commotion. However, the background radiation of the explosion is scattered everywhere. Even before that, there was an empty background. But knowing about the existence of a photon star and an electron star and the importance of spin is a rather inspiring source of information. Many questions arise from this, but one is more interesting than the others. Can the emergence of time and spatial expansion also affect the expansion of matter, in addition to increasing distances? Biological material has a tendency to increase. Emptiness How big was the emptiness? Very big. There was an infinite emptiness. How did you understand that it was infinite? Because everything that is now did not exist then. The bigger and infinite emptiness seems, the greater the probability that something is in it. So: since we exist, it is much easier to believe that matter conquered the universe, not the other way around. And referring to the cunning and learning ability of energy, it is no wonder that it emerged, because look how many times it has emerged from nothing. Photon, neutrino 3, electron, Quark 6 helpers, proton, neutron, atom, molecule, time, stars, matter118, galaxies, Planets, a biological similar system connected to the previous one and everything is in several guises. There is no doubt that it will continue to develop. It has more promising prospects than humanity, for now certainly and inspires awe. Compared to it, we are only at the first photons, i.e. we have made the first spin and have managed to create a small defense against the universe, and emptiness, but there is no special backup plan either. Just don't misunderstand. This is a pretty serious text and explanation. All rights reserved!

Mask, very useful article, but where it all started remained unclear. Of course, the creation of possible matter is explained here, but now there is a new question, where did the so-called universe boundaries start, or how did the densification of the void develop, something had to influence it?

Mask, is there only one infinitely large void, inside of which there is another void, or are there more of them, and if there are infinitely many voids, then how are they arranged? Like, for example, the honeycombs in a beehive next to each other, or in a cluster (or clusters in a spiral, etc.)? What is between them, like the wall of the honeycomb or the void? What happens when the void or voids end, what is behind them, i.e. outside the void? Please explain, these questions have troubled me since childhood? Familiar aliens always owe me an answer here.

we finally get to God(s), to the word

There's nothing to talk about gods, it's probably fiction,,,,,,they should have evolved from something, right? If such characters even exist,,,,very hard to believe,,really abstract to the human mind,, but you can believe in anything that gives you peace of mind.

Some highly developed characters have learned to use the curve of the time-space continuity. Sometimes, rarely, it happens that matter is thrown into a vortex of energy, then an opening is formed for a moment, like a gate, through which we can also accidentally get into other dimensions. You may never get back, or you will end up in another place on Earth or in space, or you will end up back. It's nonsense if you end up behind the void mentioned earlier in the topic of the formation of matter ...

Very useful story, I, for one, wouldn't have bothered to write such a long story, how long did it take to write it???

We really only exist in appearance now. Everything is an illusion, we are trapped in God's dream, and when he wakes up, it will all be over.