The new quantum processors are more and more powerful.

Quantum entanglement and photon clouds can be the heart of next-generation quantum microchips. The idea is that there are two graphene layers and between them is the photon cloud. The quantum entanglement will form through that photon cloud in which photons are superpositioned and entangled. That energy bridge transfer energy to the photon cloud.

That kind of system is making it possible to create more and more powerful computers. The worst problem with the photonic superposition is that it's quite a short-term system. That thing means that the quantum computers must be re-adjust after a short time.

Quantum memristors are making it possible that the re-adjustment of the quantum computer can be automatized. The system will take the positions that are used in operations from memristors. That allows the quantum computer can continue its operation after re-adjustment. And the superconductors that can let electricity travel in only one direction are making it possible to create the diodes for superconducting microprocessors.

But if the system makers can create stable superpositions. That thing can make dreams true. Making a stable quantum computer is possible in the case that the superpositions and entanglements are made between extremely high-energy particles. And the most suitable for that purpose is the quantum-size black holes.

The idea is that electrons are turned into quantum black holes by pumping them with energy. And then the wave-movement is pulled between those black holes. That wave movement is acting as the belt in gear. And it can transfer energy to the photon cloud around it. But the problem is how to make those quantum-size black holes? The stable quantum computer that can operate even for years without breaks is the greatest dream of mankind.

The problem with solid-state quantum microprocessors is that they require superconducting. The superconducting makes it possible that information keeps its form while it travels through the quantum system. There is lots of work to do before we will replace our laptops by using quantum processors.

But maybe someday we would equip ourselves by using the quantum computers that are so easy to use as modern binary computers are. The problem is that the systems require very much energy, and they must be re-adjust after a while.

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