The digital "demon": how to increase the quantum computer's power? (Part2)

The key element in qubit is how users can be sure that its value is zero before the system starts to transfer data to it. The normal way is to decrease the temperature of the qubit to zero kelvin. In fact. That thing is probably not necessary in the future.

The system can take any temperature or energy level to zero point. The zero point could be, for example, 20 degrees Celsius.

The zero point is the point. Where the system starts to transfer data to the qubit. The problem with high-temperature qubits is how to control their oscillation. But if the system can keep the energy level stable that thing can revolutionize quantum computing. When zero-point is determined. The system can make superpositions and entangled pairs of elementary particles.

And then the system will operate for a while. The problem is that the energy level between both ends of quantum entanglement must not be the same.

If the energy level of superpositioned and entangled particles is the same. That thing breaks the quantum entanglement. The reason for that is when both particles reach the same energy level the wave movement that they send pushes those particles away from each other.

That means the time that the system can keep quantum entanglement is limited. So if we return to Maxwell's demon model we can maximize the time that quantum entanglement remains by using the simple thing. We can put another side of the quantum entanglement to a minimum energy level.

And the other side will rise to maximum energy level. When the difference between energy levels of both sides of quantum entanglement is very high, that maximizes the time that the system can maintain the superposition and entanglement.

But then we can increase the quantum computer's power by using the model where the zero point of the qubit is determined individually in each case. The system can determine the zero point as an example to 20 degrees Celsius. But then the system must keep the energy level or temperature of the qubit stable.

The problem is that the hot or warm qubit must not oscillate. So the system must protect the qubit. Or the data will not keep its form. The problem with high-temperature qubits is the oscillation.

But other ways. As I wrote earlier, the system can determine any temperature or energy level to zero point. If the system can keep the oscillation of the qubit in its form that can be a revolutionary advance in quantum technology.

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