Theoretical teleportation is a quite simple thing. Developers must just push information in the quantum channel. And then they can transport it over long distances. The idea is similar to taking a tube and pushing paper in there using the rod. We can push the paper through the rod and then read the text that we wrote in there before we put it in a tube. But then we can see that the paper is not like the paper.
That we put in the tube. There are wrinkles on that paper. Information is entirety. It contains paper and text. Text is significant information to us. And we don't normally think. The information changes when the paper turns wrinkled. The information form changes and that makes teleportation impossible.
Or we can teleport anything. But the problem is that we cannot return information in the same form. That we sent it. The changes in information flow destroy the form of information. And if researchers can deny that change they can make real-world world teleportation machines.
The normal models of teleportation are made for homogenous, or monoparticle structures. In normal life complex systems involve multiple types of particles. And there is lots of space in there. The normal, natural systems are like cushions. And if we want to teleport natural systems we must push all particles at the same time.
The problem is that the quantum channel is so small. And complex systems are like cushions that we try to push through the water hose.
All systems involve multiple subsystems. When we look at as an example the ball pits every single ball in the system is an individual system. Every single atom, its electron shells, atom's core, proton, and neutron form an individual system that we can separate from the main system. That idea is the key element in quantum engineering. One single particle can pump the entire system through space and time if it can create the quantum channel between two systems.
When information travels through the system it acts like a quantum-size thermal pump. The beam that travels through the system pulls quantum fields with it. That forms a situation where the beam or channel that travels through the system can pump it into it. Information that travels between systems travels in a so-called quantum channel.
When information travels between superpositioned and entangled particles it can take large particles or systems with it. The idea is that if the system is between superpositioned and entangled particles the information pushes the system through the quantum channel if that effect continues long enough. The problem with quantum teleportation is how to remove outside effects from that quantum channel. In complex system teleportation, the problem is that the information should return to the original form.
The universe is full of whirs. The size of the whirls is different. But the plasma whirl around the quasar looks similar to the quantum whirls around spintronics. It's possible to put the quasars into superposition and quantum entanglement. But that thing is impossible between plasma layers. There is too much space in plasma and that makes superposition and entanglement impossible between plasma layers around black holes.
But it's possible to make superposition and quantum entanglement between two black holes. In superposition and quantum entanglement, data travels between two superpositioned particles in the quantum strings. That quantum string travels in a quantum channel. Does the information travel faster than light? No, but in the quantum channel information travels faster than it travels outside that channel.
Pauli's exclusion principle means. That there cannot be two identical particles (or structures) in the same quantum system. The superposition and quantum entanglement mean that there are identical particles (or structures) in the system that oscillate at the same frequency. Those particles are not identical, because their energy levels are different.
That causes a situation where information starts to travel between those particles. If that thing continues long enough the entire particle (or structure) travels through that quantum channel.
The gravitational superposition means that a more powerful gravity field puts a less powerful gravity field oscillating in the same frequency. If we think of things like black holes the plasma around them can transmit information from their environment in that superposition.
Superconductors are interesting things. They can form the smooth electromagnetic wave around them. This thing makes it possible to use them in quantum computing and other quantum technology. The problem with quantum technology is transmitting information through the system without artifacts. The artifact means non-controlled effects in the system.
And that makes it impossible to create quantum laptops. The non-controlled and non-predicted effect that is not measured makes it impossible to calculate that effect backward. The idea in this model is that the system removes energy levels of the outcoming effect. Normally that thing is easy if we think about things like mathematics. But in quantum systems, there are lots of energy levels in qubits that it must calculate.
Quantum systems are making quantum entanglements by using quantum dots. The transmitting system takes touch with the quantum dots in the receiving system. Radiation acts like rods in the normal mechanical system. The qubits are like wheels and quantum dots are holes where those rods touch. The system will take touch with those quantum dots and take the receiving particle with it That is one way to think about quantum computing.
And why making the quantum entanglements with the room temperature systems is impossible. We can say that there are too small numbers of quantum dots in the system. Or there is too much empty space in a system that those quantum dots cannot put the system into superposition. The room temperature systems are like ball pits. It's possible.
That the other system puts rods into that thing. But those rods just push balls away. So how to make the other ball pit rotate with the transmitting ball pit? The answer is that we can put water in the ball pits and freeze it. That makes it possible to rotate the ball pits using the rods. That is between them.
https://scitechdaily.com/rewriting-the-rules-scientists-discover-new-superconductor-with-unconventional-properties/
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