Photonics and qubits.

Photonics is a new science. Researchers make some new things almost every day. To that new, interesting science that offers limitless possibilities. The two-photon technology can mean. The photonic version of the scanning tunneling microscope. The other photon is in the frame. And the other photon hovers above the object. When another photon hovers near the surface. That causes interactions in those photons' quantum field. And that makes it possible to scan the atom's internal structures. Quantum systems require the ability to see things that the system can make interactions. 

That means the system that sees the position of things like electrons makes it possible to create Rydberg states in atoms with ultimate accuracy. Another thing is that this kind of system can increase the power of the quantum data transmissions. The system can create hollow laser beams. And then shoot the photons their data is stored in this quantum channel. The quantum channel protects information in the quantum channel. 

But quantum computers can be more advanced. If the system can use superconducting wires to transport information. The information can travel in the superconducting wire. Or it can transported between two superpositioned and entangled photons that hover in that quantum field. In the last version, the quantum field protects data in the quantum channel. 

What if we create a system where the wire moves and data stand in a static place or point on the wire? The thing in room temperature quantum computers is that. 

The Hall effect or resistance destroys data in the wire. But if the system stores data in a static point and moves that point. 

That eliminates the Hall effect. So the idea is that the wire moves and the data stays in static lace in the wire. 

"The general definition of a qubit as the quantum state of a two-level quantum system." (Wikipedia, Qubit)

The quantum computer is very close to the analog computer. We can think of the superposition and quantum entanglement we can think of that system as a C-cassette-style component. The difference between this system is that the system writes data to tape. Then it transports that point to the receiver. Then the data is in the static point. The moving tape moves data to the receiver. 

It's possible to load information row to line into the C-cassettes or series of C-cassettes and then drive that data to the receiver. It is easier to use individual tape for each quantum state. Those cassettes can benefit nanotechnology. 

We can think that qubit's states are strings. Every string has values 0 and 1.  So, theoretically is possible to create a qubit using the line of microprocessors. That means the computer line can used to make the virtual quantum computer.

Quantum computers can store information in the DNA. In that chemical version, the base pairs A, T, and G, C can be 1 and 0. ( (AT) =1 and (GC)=0) or every base can be the individual state of the qubit. A=1, T=2, G=3, C=4. In that case, the pair numbers can be 1 in those states. And pairless can be zero. The electric impulse that tells if the computer will shut down. 

The system writes the data to tape. And then tape transports that point into the reader that transports data to output.  But can that kind of analog computer be the quantum computer simulation or the quantum computer that can operate at room temperature? 

There is a model where the very thin iron wires can store data. Then those iron wires move that point in them into the receiver. The idea is that the wire that moves can keep the information in its original form. The problem is that the resistance, or Hall field destroys the data structure that travels over the wire. But what if wire travels and data stands at the same point? The idea is that wire travels between two points. The writer writes data to the wire. And then the wire moves that point like a tape recorder to the receiver. 

https://scitechdaily.com/a-million-qubits-within-reach-as-microsoft-redefines-quantum-computing/

https://scitechdaily.com/scientists-just-cracked-the-code-to-supercharge-quantum-networks/

https://scitechdaily.com/seeing-the-invisible-world-scientists-decipher-two-photon-vision/

https://en.wikipedia.org/wiki/Base_pair

https://en.wikipedia.org/wiki/Hall_effect

https://en.wikipedia.org/wiki/Qubit