Qubits are like small hard disks

Qubits are like small hard disks

The form of a molecular qubit is the fullerene or the hybrid molecule, which stores the data, and then it would resend it to the microchannel, which makes it possible to transform the row of bits to the form of the line of the bits. And this ability is the key element in the quantum computer. The idea in that ultimate calculation machine is that the data goes in lines, not rows, and because the processor is working in a larger or wider area, that makes quantum computer extremely powerful tool for calculating things, and it is faster than any modern computer has been before.

But how send the bits to microchannel at the same time? One version of this is loading the data to the molecule, which is in the chamber, and then the data can send in wires of the microchannel at the same time.

When we are talking about stable qubits, the fullerene or some hybrid molecules, what are transferring the data, and make the quantum computer possible, somebody might asking, where that kind of qubit is needed, and the answer is simple. Those qubit molecules are in the primary role, when the bits, what is traveling in the row would share to microchannel at the same time, and that thing would put the bits travel in the lines, not rows. And when those bits travel at to the end of the microchannel, they would connect, and then share them to the screens.

The problem with those molecular qubits, what is oscillating in the chamber, and act as the switch is that they must transform the row of the bits to the line of the bits and send them forward in the same time, and that thing requires that the oscillation of the qubit must be fully controlled, what requires extremely low temperatures. The qubit acts like the miniature hard disk, and it stores the data, which is pumped in there. Then the molecule would expand, and send the data to the microchannel at the same time, as I mentioned before.

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