How to make quantum entanglement to solid semiconductor cube?

The idea in the solid qubit system in the boron arsenide is that the superposition is made by using another atom type in that two atomic systems. The superposition is made by using the electromagnetic fields of those atoms. And the superposition is pulled through the third atom that is forming that boron arsenide cube. The quantum entanglement would make by using smaller atoms.

atoms can be anything like chlorine and hydrogen. The idea is that the data must transmit to another atom group. And another atom group will make the superposition. Diagram 1 shows how quantum entanglement travels through an atom. Which is used to transmit data to the superposition.

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1:) Superpositioned and entangled atoms which superposition travels through the bigger atom. Or bigger atoms quantum field.

2:) Bigger atom that transmits oscillation to the quantum entanglement. The bigger atom will stress by using electromagnetic radiation. And that thing will transmit data to quantum entanglement.

The oscillation of the quantum entanglement will transmit data to the larger atom. That thing could solve the input-output problem between quantum and binary systems.

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The system stresses the smaller atoms by electromagnetic radiation. Then the creators of the system will make sure that the larger atom is in the line where the superposition of those electromagnetic fields will travel. A scanning tunneling microscope will transmit data to the larger atoms. The data can also transmit by using superpositioned and entangled photons.

After that, the oscillation of those atoms will transmit data to the quantum entanglements. That thing is one of the versions of the solid qubits. The problem of solid qubits is always been the same. How to transmit data to the qubit and back to the binary system? The system can simply pull the quantum entanglement through the semiconductor. Then that semiconductor can transmit data back and forth to that quantum system.

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