The element Copernicium (Cn) (Element 112)
Element 112 in the periodic table of elements or copernicium (chemical symbol: Cn) is the 12th group of elements. That means this metal is so-called transition alcalde metal, and in the same group with mercury, zinc, and cadmium. That means that the copernicium might be liquid metal, and sometimes people have thought, that could the strange quicksilver, what is connected with UFO-power systems of high-energy lightweight nuclear reactors copernicium?
If we would someday benefit that kind of nuclear material in some still theoretical reactors, we must put that element in the particle accelerator, what would slow the time on the radioactive mass. The thing is that superheavy elements make possible to create extremely powerful, but small size reactors.
The problem is that storing those elements what can be existed is extremely difficult, and that means the benefiting of those particles would become in use of practical solutions in the future. But who knows what is going on those special laboratories, where this kind of research work is done.
The evidence for that thing that the mysterious mercury could be copernicium is mentioned, that the longest life isotope of copernicium lifetime is 32 seconds, and the researchers should conclude the form of this element. But here we must say, that there have been only a couple of atoms of that element ever existed. The thing is that I don't know, what method the finder of that element used to produce copernicium. If that man used low-energy linear particle accelerator, that means that the production of a couple of atoms of copernicium would be easy, but this kind of things have a couple of problems if we would try to make this kind of things in practical life.
The first thing is that we must find two elements, what we want to use in a fusion reaction. Those elements should have ion form, what have different polarity because the opposite polarity would help to aim the ion ray. And then the ions would shoot through the particle accelerator to the chamber, where those atoms would connect if the fusion would have enough energy.
Or actually, the energy level must be precisely right, or the particles would destroy each other in the impact if the accelerators would operate in too high energy level. And fusion method has a couple of other problems. When the particles impact together, there is a possibility that part of them would turn to energy, and that's why we cannot produce any elements just by shooting two ionized lighter elements together.
At first, the energy level of the particle accelerator must adjust precisely right. Then the ion rays must target that way, the fusion would be possible. Aiming of the system is difficult, and then the spectroscope must aim at the right point. The camera what will take images of the spectrum line must operate with very high speed, that it can see the line, what the element, what has extremely short lifetime sends.
And those elements, what is researched in this way are very high radioactive. In fact, in theory, we could produce hundreds or thousands of new artificial elements, but the thing is that those elements must have some mean. Chemically the structure of the electron cores is always following the system what is involving in the periodic table of elements, but the spectroscope is the only way, how researchers can confirm the existence of the new element. The short existence along with the low number of those atoms makes chemical tests with those atoms impossible.
Element 112 in the periodic table of elements or copernicium (chemical symbol: Cn) is the 12th group of elements. That means this metal is so-called transition alcalde metal, and in the same group with mercury, zinc, and cadmium. That means that the copernicium might be liquid metal, and sometimes people have thought, that could the strange quicksilver, what is connected with UFO-power systems of high-energy lightweight nuclear reactors copernicium?
If we would someday benefit that kind of nuclear material in some still theoretical reactors, we must put that element in the particle accelerator, what would slow the time on the radioactive mass. The thing is that superheavy elements make possible to create extremely powerful, but small size reactors.
The problem is that storing those elements what can be existed is extremely difficult, and that means the benefiting of those particles would become in use of practical solutions in the future. But who knows what is going on those special laboratories, where this kind of research work is done.
The evidence for that thing that the mysterious mercury could be copernicium is mentioned, that the longest life isotope of copernicium lifetime is 32 seconds, and the researchers should conclude the form of this element. But here we must say, that there have been only a couple of atoms of that element ever existed. The thing is that I don't know, what method the finder of that element used to produce copernicium. If that man used low-energy linear particle accelerator, that means that the production of a couple of atoms of copernicium would be easy, but this kind of things have a couple of problems if we would try to make this kind of things in practical life.
The first thing is that we must find two elements, what we want to use in a fusion reaction. Those elements should have ion form, what have different polarity because the opposite polarity would help to aim the ion ray. And then the ions would shoot through the particle accelerator to the chamber, where those atoms would connect if the fusion would have enough energy.
Or actually, the energy level must be precisely right, or the particles would destroy each other in the impact if the accelerators would operate in too high energy level. And fusion method has a couple of other problems. When the particles impact together, there is a possibility that part of them would turn to energy, and that's why we cannot produce any elements just by shooting two ionized lighter elements together.
At first, the energy level of the particle accelerator must adjust precisely right. Then the ion rays must target that way, the fusion would be possible. Aiming of the system is difficult, and then the spectroscope must aim at the right point. The camera what will take images of the spectrum line must operate with very high speed, that it can see the line, what the element, what has extremely short lifetime sends.
And those elements, what is researched in this way are very high radioactive. In fact, in theory, we could produce hundreds or thousands of new artificial elements, but the thing is that those elements must have some mean. Chemically the structure of the electron cores is always following the system what is involving in the periodic table of elements, but the spectroscope is the only way, how researchers can confirm the existence of the new element. The short existence along with the low number of those atoms makes chemical tests with those atoms impossible.
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