The thing is that quantum computing is so young that almost all new designs are revolutionizing that thing. The major problem with quantum computers is that quantum computers can keep superposition and quantum entanglement very short time. In this text, "superposition" means "quantum superposition".
Then the quantum computers must re-adjust. And if we want to make a quantum computer that can keep its adjustments during a long-term calculation process that requires new types of qubits. There is another way to make a qubit. In that process, the data will store in electrons. And then those electrons can shoot to the receiver.
In that system, the electron can have two layers. When the energy load of the electron is <x (smaller than x) the value is one. And if the value of electron is X< (higher than x) the value is two. The zero line is a separately installed electric line that tells if the system is shut down. In the quantum system can be multiple electron lines. And each electron line is a certain main level of the qubit.
So if there are four electron lines there is a minimum of 4X2=8 states in that very simple qubit. Even if that system is less powerful than the high-power systems. But those systems are less vulnerable to outcoming radiation. And they can make portable quantum systems possible.
Researchers can replace those electron channels with electric wires or lasers. The thing is that this kind of system makes lightweight systems that are more powerful than regular binary computers possible.
The idea of those systems is similar to the electron lines. But the idea is that if the voltage of those lines is below a certain level the value is one. And if the voltage level in those wires is higher than that level the value is two.
The thing with quantum entanglement is that the energy level in that system must not be stable. Information travels in superposition quantum entanglement only if another side is at a higher energy level than the other.
If both sides of quantum entanglement reach the same energy level. That breaks the quantum entanglement and superposition.
The superposition and entanglement can stay longer. If the energy will pump only to the other side of that thing. And then, the energy must pump away from another side of the quantum entanglement.
*So if the system shoots a photon (or photons) with a certain energy level to another side of the quantum entanglement
*And then from another side, the system shoots photons out with the same energy level that can create stable superpositioned quantum entanglement.
There is one thing that can keep the energy levels in the quantum superposition at different levels. Another version is to remove the same energy mass in the form of wave motion that increased to that system. One of the system's problems is how to make the energy or information keep its form and quantum states.
There is possible to use two rows of 2-D atoms that are used in artificial black holes. The system makes electron-hole series in those atoms. And then. The system puts those electron holes to superposition and quantum entanglement. That makes it possible to make a series of superpositions and quantum entanglements between those atom lines.
The system can work like this: at first, the system makes superposition between elementary particles whose energy levels are as far from each other as possible. In that case, superposition on another side of quantum entanglement, the energy level is as high as possible. And in another side, the superposition and entanglement energy levels are low as possible.
That thing maximizes time where energy can flow from another side to another in quantum entanglement. And that energy or information flow is urgent for a quantum computer's function.
When the energy level in that superpositioned and entangled particle pair reaches balance. That destroys the quantum entanglement. So if energy levels of those superpositioned and entangled particles are as far as possible that maximizes the operational time.
https://www.beforethebang.org/post/quantum-entanglement-for-the-first-time-seen-on-a-large-scale
https://www.freeastroscience.com/2021/04/what-is-quantum-entanglement.html
https://www.nature.com/articles/s41467-022-34614-w
https://en.wikipedia.org/wiki/Quantum_entanglement
https://en.wikipedia.org/wiki/Quantum_superposition
https://www.sciencealert.com/scientists-created-a-black-hole-in-the-lab-and-then-it-started-to-glow
https://designandinnovationtales.blogspot.com/
Comments
Post a Comment