The photon brains and Rydberg atoms are the next-generation tools for data-handling processes. The laser rays can use themselves as qubits, and the certain color of the laser can be the certain state of the qubit. The ability to photograph single photons is making it possible to use the individual photons as the qubits. A certain level of brightness is a certain state of the qubit.
The lasers can make ionized atom chains, which can use in quantum computers. The laser can stabilize the chains of ionized atoms or electrons. And if those structures are stress by using outcoming radiation, that thing makes it possible to create the network-based quantum data handling system.
Lasers can be used to create a quantum network, that is using only photons. The outcoming radiation will adjust the power of the laser rays what can use as a qubit. The photon qubit is stable against electromagnetic radiation. As I wrote earlier the ability to take images of single photons. Make it possible to use individual photons as qubits. In that case, a certain brightness means the certain state of the photon qubit.
Theoretically, the quantum computer is a simple tool. The simplified model of that thing is only the electromagnetic field, which power is the certain state of the qubit. The system is like the wire, where is the voltage meter. Each level of the voltage meter is a certain state of the qubit. In some other models between a certain distance of the center transmitter. The distance of the receiver is the certain state of the qubit.
But for work perfectly this system requires that the distance between transmitter and receivers must be long enough. The system cuts the data into pieces. Those pieces send to the receivers and then connect back to one entirety.
There is the possibility to make the acoustic qubit by sending the sound waves to the decibel meter, and each level of the power of the sound is the certain state of the qubit. The voice or pressure impulses can send to the crystals, which are chancing it to the electric vortex. But I don't know if the acoustic qubits were never tested in real-life conditions.
The quantum annealing system is not necessarily used only in the quantum computer. It can be the ion field, which brightness is chancing when the outcoming radiation affects it. When the brightness or energy stress of the ions is chancing, the ion cloud is sending the electromagnetic radiation, which can observe by using telescopes. So quantum annealing technology allows making extremely large ion antennas that can use to capture extremely weak radio signals.
Quantum annealing makes it possible to create table-size quantum computers. While atoms are stressed their quantum fields are expanding. In quantum annealing systems, certain atoms are stressed with electromagnetic radiation. So when those atoms are stress they are sending the radiation with their specific frequency when they are delivering extra energy.
The base system which uses pure ions and has 5 qubits requires the use of five different elements. But increasing the accuracy of the energy stress is possible to store data also in individual electrons. That thing is possible using quantum lasers can increase the number of states of qubits. If the individual electrons are stressed in the electron cores that thing turns those atoms into Rydberg atoms.
By using Rydberg atoms there is possible to make the qubits, that have hundreds of states. There could be the main states in the qubits and then the sub-states. That is making the data transport and security more effective.
And that thing makes them possible to receive the data by observing those quantum fields by using radio telescopes or some other radio receivers. The idea of that kind of system is that every single element is sending the radiation with its specific frequency. If the system uses uncommon elements like gold or uranium, the radiation that those atoms are sending is easier to separate than radiation which sources are the common elements.
But space where the quantum annealing system is can be isolated and protected from the outcoming radiation. And that makes it possible to use things like iron. Or some other common metals or gases as the heart of quantum annealing systems.
The quantum lasers make it possible to stress even the individual atoms, and they can install to the microchips, which are using the quantum annealing systems. Those systems can also use microscopic carbon crystals for creating the quantum annealing effect. That system can install in the small-size coolers, which are minimizing the resonance of the electric systems.
()https://en.wikipedia.org/wiki/Rydberg_atom
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