The quantum supercomputer is going to test drive

The quantum supercomputer is going to test drive

The researchers of the University of Stuttgart have made the quantum computer prototype, which is benefiting Rydberg atoms. That system can be revolutionary for quantum computing.

The image above this text shows how the qubit can work, and as you see the water molecule can operate as the qubit or extremely small transistor. The hydrogen atoms can work as stem and collector. And the hydrogen atom can work as an emitter. The molecule can hover above the graphene layer.

In the case that the water molecule is operating as a qubit, the system would use the electrons of the oxygen atom as the data transmitters. The laser ray would aim at the water molecule, and it will be sending the oscillation forward. In that case, one or more electrons of the atoms will extremely high principal quantum number, which makes them Rydberg atoms.

So the electromagnetic stress to electrons would make them send the photons, and the hydrogen atoms would be used to turn the qubit in the right direction. In other versions, the single-atom chains are connected to the water molecule, and then they can deliver data to that molecule. That structure can make between two graphene layers, and it can make the new type of extremely small computers possible even if they are not suitable for quantum computers.

Graphene and the high-temperature superconductors

The graphene could be the key to the high-temperature superconductor. The chains of carbon atoms can form the extremely thin electric wire. The thickness of the electrical conductor directly affects the electrical resistance. So if researchers could make the electric wire what is the chain of the single atoms, that thing would make it possible to create the high-temperature superconductors. For the single-atom chains and layers, the resistance is minimum. And graphene is the single-atomic structure, that can be used to make nanotubes.

The nanotubes are the interesting thing in the point of view of the superconductivity is that the resistance in the nanotubes is very weak. But the nanotubes can also protect the atom chains, which are used to transport the data. In larger-scale solutions, the single-atom chains are put between the graphene layers that are protecting the single-atom chains. That kind of structure might make the new type of quantum computers and miniaturized processors possible.

How to make programs that are benefiting qubits? If those programs that are driven straight on the quantum layer are possible to make, that will make the traditional 0/1 bit computers history.

The problem with quantum computers is how to make programs for that kind of system? The programming algorithm and operating system of the quantum computer should benefit the multi-layer qubit. By using this kind of thing the dream about the table-size quantum computer is closer than ever.

But that requires that for the computer is written the operating system and the programs. And that allows driving programs on the quantum computer layer. If that thing is possible, it would make the revolution for computing.

In traditional models, the quantum computer is used through the normal computer. Traditionally the program is written for the 0/1 bit systems, and then the traditional 0/1 system will try to transform the code to the qubit or quantum computer. But if the quantum computer itself can be equipped with the operating system and the programming algorithm would make it more suitable for high-power computing.

https://www.coursera.org/lecture/quantum-computing-algorithms/quantum-computer-prototype-diy-dCKRO

https://www.opli.net/opli_magazine/eo/2021/quantum-computer-on-the-way-to-prototype-feb-news/?fbclid=IwAR1kaZhBloLaNpe9HdYBWPE6C_sX0a3x7sFfb55CK1SMTWwF_MnIaBL6lhE

https://physicsworld.com/a/twisted-trilayer-graphene-could-help-make-high-temperature-superconductors/

https://www.uni-stuttgart.de/en/university/news/press-release/Quantum-computer-on-the-way-to-prototype-00001/

https://spectrum.ieee.org/tech-talk/computing/software/qscout-sandia-open-source-quantum-computer-and-jaqal-quantum-assembly-language

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

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

Image I: https://www.opli.net/media/11082/09_21_qryddemo1.jpg

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