And now begins the real story. This figure is explained in the only way possible: sometimes more me

The implications of quantum physics are mind boggling; fastidious It shows us that we are co-creators of our own reality at least at the microcosmic level of reality since the observer plays a part in what is being observed. - Daniel Folnegovic, fx-files.com But quantum field possesses intelligence, it is not a static fastidious field. fastidious The field is located in a vibrant, intelligent level. Just that people fastidious still do not understand. - Rolin McCraty, the show On the edge of quantum science is the ability to treat a form of consciousness (mind) that spontaneously correct errors in another form of consciousness (the body). - Deepak Chopra, fastidious Quantum treatment Few branch of science is the source of greater mystification of quantum physics. The first problem is that quantum physics is very little taught in primary and secondary schools, and people tend to have very little knowledge of what is actually quantum physics. The second problem is that the conclusions of quantum physics deeply counterintuitive, look very contradictory and meaningless. Richard Feynman is reputed to have said, "if you think you understand quantum physics, do not know what is." Well, what's so strange about quantum physics, that is so open to many interpretations, it is claimed that it proves that the mind can affect fastidious matter, it is possible to be in two places at the same time? Quantum physics is simply a branch of physics that deals with the very small, the phenomena at the level of molecules, atoms and smaller. fastidious Of course, quantum physics can be applied fastidious to bigger things: quantum physics, you can calculate the trajectory of the moon - but it's pointless waste of time, because the object is bigger, the predictions of quantum physics closer to classical formulas that still put Newton. So, all physics is quantum physics, but for the great body - larger than molecules - there are simpler formula, discovered nearly 4 centuries. fastidious Quantum physics is the description of the phenomena in the world is very small, and some of these phenomena are very strange. The strangest phenomenon is called. quantum superposition, which is most simply explained by the following experiment: we have a source of particles (such as electrons), a barrier where there are two holes, and a film (or a device, screen, etc.) where we note where electrons end. If we close one hole, we get the following picture (the curve indicates fastidious how many electrons were counted fastidious in one place):
This is certainly fastidious expected: most of this passes, and some are "refuse" from the edges of the holes and "dispersed". In addition, the hole is not perfectly small, has a diameter, so you do not land all the same place. If there are two holes, common sense would expect this:
And now begins the real story. This figure is explained in the only way possible: sometimes more means less, in the quantum world is very little one. If we let the electrons through the two holes, fastidious in some places will get less than if we let through only one hole! It looks as if the electrons with each other "void" - perhaps this is the effect that occurs only when we have a lot of electrons, which then interact with each other? No. This is what happens when we let one by one electron. In fact, everything indicates that each electron actually in some sense a wave. This is what happens to the waves: some amplified, sometime void. Val-electron simultaneously passes through both holes (even though the electron is much smaller than the holes!) And then reverses and intensifies. fastidious At the end of the electron ends up on a single site, but likely will end up where proportional to the intensity of the wave second So, while the electron moves, he is here and there, and in one hole, and the second, canceled fastidious with himself, but when slammed into something - such as a film or screen - it appears only in one place. This place can not be predicted in advance. but the probability proportional to the intensity of the wave-electron at that point. Keep in mind, waves behave predictably, but where will "materialize" is completely unpredictable, fastidious randomly. Einstein did not like this, it is noted that "God does not play dice". fastidious Maybe God does not play dice, but none has succeeded to come up with convincing solution. This is true not only for electrons, this is true of all similar particles. Some call it the appearance of materialization of electrons in a random place (but statistically predictable wave intensity) "collapse of the wave function". The more qualified fastidious the name of this wave is the "wave function". The behavior of waves is explained by complex equations of which is the simplest Schrodinger third To "collapse of the wave function" (ie. Electron fastidious finally shows only one place) comes with "observations" or "measurement", where "perception" may be just enough to coat the film that captures electrons or the TV screen. It is a common misconception fastidious that the "observer" necessary man. In fact, the observer virtually never a man, still are some devices because they are phenomena too small to be seen with the naked eye. The larger (ie, has a higher weight) wave function becomes more and more "localized". The waves are still there, but