Theoretically is the possibility to put the things like electrons into one certain-looking entirety. It's possible, that researchers can calculate the point where the forces like quantum gravitation and quantum fields make it possible. That particle can remain at a certain distance and a certain position from another particle.
The problem with quantum systems is that they are not homogenous. Even in the cleanest possible systems are always quarks and photons. And that thing makes the system hard to remain as one entirety. Even if the distance between particles is calculated so accurately that they could stay in one form the other particles or wave motion brings artifacts or non-controlled events in that system.
The thing is that the quantum systems are hard to control because outcoming effects are not possible to calculate. There is a theoretical possibility to create a quark or electron cloud that remains in a certain form. But the outcoming effect makes that thing at least very difficult to make in real life.
To see the entire quantum system observer must stay outside it. But if the observer is inside the system it's hard to detect the entirety.
The image above shows why quantum systems are hard to detect if an observer is inside a certain quantum system. When there is some dominating effect in that system. That dominating effect covers all other effects under it. And dominating effect makes it very difficult to detect other effects. If we are under that streetlight.
We would not see buildings around that location. This image shows that if the observer is outside the system observer can observe it. But if you are inside the system you are hard to see outside things. The fact is that dominating effect in the quantum system acts like a streetlight. It covers all other details under its shine.
Whenever the outcoming energy impacts the quantum system the participants of that system are sending radiation. And that radiation covers the radiation that comes outside the system.
Things like energy waves can also cover another quantum system under it. Standing energy- or information wave can cover the existence of another quantum system.
And then another thing is that if the energy levels of the quantum systems are different that makes it is hard to exchange information between the two quantum systems. If the quantum system where the observer has a higher energy level than the outside system energy flows to the quantum system that is at the lower energy level.
The system that has a higher energy level is an active- or dominating participant in that model. And the system whose energy level is lower is a passive- or recessive participant of the combination of those quantum systems. The recessive participant of that system is receiving participant. The system that is a higher energy level transmits information.
Those quantum systems act like radios. When another participant transmits information the transmitter cannot make sure that the receiver has received that information.
So when information travels to one side between two quantum systems the recessive system detects the dominating system. But the dominating system cannot detect the recessive system because information travels to the recessive system. There is required some kind of echo that raises the energy level of the receiving system so high that it can send energy- or information impulse to the transmitting system.
Energy is like a hill. When another participant is at a lower energy level it must raise something in it to a higher energy level than the transmitter so that it can send the information against that hill so that it can reach the transmitter.
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