How do you think a person can influence the universe? On the material world, what is around us? Many will say that we change it every second with the help of human strength and reason. And they will be right. We subjugate our planet, launch rockets into space, and transmit messages at the speed of light. But today I want to tell you about how great our influence on the reality around us really is.
If you have ever been fond of physics, then you have probably heard of such a phenomenon as quantum uncertainty, discovered by Werner Heisenberg in 1927. I will try to clearly explain what this phenomenon is. We all know that our world consists of atoms, and they, in turn, are made of elementary particles such as electrons, quanta and bosons. Physicists have failed to rationally explain the uncertainty principle. Therefore, they had no choice but to simply accept it as given, without any evidence. Take it as law. Since this is happening, then let it happen. These small particles simply blew the roof off many scientists of that time, as they simply did not lend themselves to any logical explanation. I assure you that you will be very surprised when you understand the essence of the problem.
The experiment was carried out: A source emitting a stream of electrons towards a special screen with a photographic plate. But it's not that simple. A barrier in the form of a copper plate with two slits was placed on the path of the electrons. Any sane person will say that after the experiment there will be two illuminated stripes on the screen opposite the slots. Since we remember from school that electrons are just small charged particles revolving around the nuclei of atoms. Electrons can be detached from them and pass through the holes of the copper plate. This is what ordinary matter would do. Well, that was not the case. In reality, a much more complex pattern of alternating black and white stripes appears on the screen. The fact is that when electrons pass through the slits, they begin to behave not like particles, but like waves (just like photons, particles of light, can simultaneously be waves). Then these waves interact in space, somewhere weakening, and somewhere reinforcing each other, and as a result, a complex picture of alternating light and dark stripes appears on the screen. In this case, the result of the experiment does not change, and if electrons are sent through the slit not in a continuous stream, but one by one, even one particle can be a wave at the same time. Even one electron can pass through two slits at the same time. But what has the observer to do with it? With him, the already complicated story became even more complicated. When in such experiments physicists tried to fix with the help of devices through which slit the electron actually passes, the picture on the screen changed dramatically and became "classical": two illuminated areas opposite the slits and no alternating stripes.and as a result, a complex pattern of alternating light and dark stripes appears on the screen. In this case, the result of the experiment does not change, and if electrons are sent through the slit not in a continuous stream, but one by one, even one particle can be a wave at the same time. Even one electron can pass through two slits at the same time. But what has the observer to do with it? With him, the already complicated story became even more complicated. When in such experiments physicists tried to fix with the help of devices through which slit the electron actually passes, the picture on the screen changed dramatically and became "classical": two illuminated areas opposite the slits and no alternating stripes.and as a result, a complex pattern of alternating light and dark stripes appears on the screen. In this case, the result of the experiment does not change, and if electrons are sent through the slit not in a continuous stream, but one by one, even one particle can be simultaneously a wave. Even one electron can pass through two slits at the same time. But what has the observer to do with it? With him, the already complicated story became even more complicated. When in such experiments physicists tried to fix with the help of devices through which slit the electron actually passes, the picture on the screen changed dramatically and became "classical": two illuminated areas opposite the slits and no alternating stripes.and if electrons are sent through the slit not in a continuous stream, but one by one, even one particle can be simultaneously a wave. Even one electron can pass through two slits at the same time. But what has the observer to do with it? With him, the already complicated story became even more complicated. When in such experiments physicists tried to fix with the help of devices through which slit the electron actually passes, the picture on the screen changed dramatically and became "classical": two illuminated areas opposite the slits and no alternating stripes.and if electrons are sent through the slit not in a continuous stream, but one by one, even one particle can be a wave at the same time. Even one electron can pass through two slits at the same time. But what has the observer to do with it? With him, the already complicated story became even more complicated. When in such experiments physicists tried to fix with the help of devices through which slit the electron actually passes, the picture on the screen changed dramatically and became "classical": two illuminated areas opposite the slits and no alternating stripes.through which slit the electron actually passes, the picture on the screen changed dramatically and became "classical": two illuminated areas opposite the slits and no alternating stripes.through which slit the electron actually passes, the picture on the screen changed dramatically and became "classic": two illuminated areas opposite the slits and no alternating stripes.
It was as if the electrons did not want to show their wave nature under the watchful eye of an observer. We adjusted to his instinctive desire to see a simple and understandable picture. Mystic? So we come to the most interesting part. If, in the absence of an observer, a part of matter turns into a wave, energy, then does this world exist while no one is looking at it?
"Does the moon exist while the mouse is not looking at it?" A. Einstein
But, one way or another, this proves one thing that our mind somehow influences our material world, and vice versa, the world is somehow connected with our mind. Recently, American scientists from the University of Michigan, led by the lead author of the study, Jimo Borjigin, conducted a study of clinical death. They refuted the majority's judgment that after clinical death the brain shuts down or shows much less activity than when the body is awake. They have demonstrated that this is not the case. Moreover, it is now known for certain that the brain is much more active during dying than when awake.
It has long been known that our nervous system emits electromagnetic waves, since its principle of action is to transmit impulses of electric current, which, in turn, creates magnetic fields. So, the brain, with all its amazing qualities, is also a semblance of a transmitting antenna. Now there are special helmets that can read the smallest impulses of our brain to control various devices: computers, robots, machines and even prostheses. It is not for nothing that this powerful quantum supercomputer, which we fondly call the brain, begins overactive activity before death. Much more powerful than in life. Many will say that this is due to a lack of oxygen, the brain begins to starve and sees hallucinations. But you must admit that in order to see hallucinations, the brain does not need such intensity. When we sleep wewe also see hallucinations, but this does not even come close to the activity of a dying person. The intensity is higher than that of the sleeper, higher than that of the awake. How can this be explained?
A person not only sees hallucinations more real than reality itself, but also remembers the most important moments of his life. That is, the brain does something similar to how the computer saves a working image of the system so that if something goes wrong, you can roll back to an earlier, working version. What happens next? The brain as a transmitter emits the quantum information of the image of its consciousness into space, into the universe. This is why I told you about quantum impermanence. It is here that the relationship between the world and consciousness can be traced. What the brain emits is no longer matter, it is electricity, electromagnetic waves, energy. And as we know, nothing appears out of nowhere, and does not disappear into nowhere. And this means that the energy will have to return. Return to this world. But already in a new person. Why, then, do we not remember information about past lives? Because information is not important. Only experience is useful to man. This is why some babies are capable of something from birth. Although no one taught them this. Experience, deep knowledge and strongest feelings are reborn. Information is swept aside as unnecessary garbage.
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This proof is based only on my personal inferences, which you are multiplying to believe or not. But you cannot argue with one. There is something in this. And this is the most that we can express in words.
Kerimov George for Science