Iron atoms and single-photon detectors can use as models for new types of models for quantum computers.

Iron atoms and single-photon detectors can use as models for new types of models for quantum computers.

Iron stars as the models of quantum computers. Maybe, iron stars, if they sometimes are real, are acting like quantum computers.

Any object in the universe can form quantum entanglement. There are some models that even black holes themselves can turn to qubits, and the wormholes are forming quantum entanglement between black hole pairs that are acting like qubits in a quantum computer.

Iron stars are the hypothetical star type that could be forming in the very cold and old universe. The iron star will get its power from the iron fusion. Or from zero point energy. Iron is not a star in the form as we know stars. It's hotter than its environment, but it is colder than some of Netunus's moons. And that effect can turn the iron star into a quantum computer.

In some visions, the hypothetical iron stars can act like quantum computers. The iron stars would exist in a very cold and old universe. The difference between the energy levels of iron stars and their environment would be higher than it's in the universe where we are living.

And that causes a situation, where energy travels out from iron stars faster than today. That turns the iron atoms' poles would be against each other. ( + against -)And iron atoms can form radial structures. In those structures the energy bridges between iron atoms are stable. And electrons can form the quantum entanglements between each other.

There is an idea that the quantum computer can be a plate. That is made of pure iron. That iron plate would be in the chamber. Where the temperature is zero Kelvin. And then system drives information in the middle of that iron plate by using a laser ray. The walls of that chamber would be magnetized, and that thing makes the iron plate form similar radial structures that hypothetical iron stars form in the extremely old universe.

The information travels through the iron plate in both directions. When the chamber sends information into that iron plate it travels in the middle of it, and then it jumps back from the standing wave. The system can also surround information through the middle of it. In that case, the system will put information travel in the system like magnetic fields traveling around planets.

Theoretically, two pure iron plates can form quantum computers. But the problem is that the electron clouds and proton's and neutron's complex structures are making the form of quantum entanglement between atoms very difficult. There is a possibility that the system can lock electrons in a certain position at a certain time by using intense light impulses. And then another laser can transport information into those electrons.

The single-photon detectors are making quantum computing easier.

The base in quantum computing is quantum entanglement. The most common versions of those quantum entanglements are superpositioned, and entangled photon pairs. But the problem is how to make information transferred to those photon pairs.

And another problem is how to make that quantum entangled photon pair deliver data back from it. The answer could be this type of detector. The problem is that the quantum entanglement is made between very small particles. And the microchips are very large in comparison with superpositioned and entangled photons. So the system should operate that way that at first, it transports information to ions.

Then those ions will transfer information to electrons that are transmitting it to the photon entanglement. The system can load those ions in nanotubes. The idea is that the ion or its electrons will lock into certain positions, and then the system bombs them by using photons or wave movement.

The system drives information first to ions and then to the quantum entanglement. Then the system starts to operate backward. The system will transport information from photons to electrons and then to the ions. That makes the sensor easier to detect that thing. This kind of system allows the creation of quantum computers that are easier to use than systems that are existed today.

https://scitechdaily.com/quantum-computings-dynamic-duo-ion-trap-meets-single-photon-detector/

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

https://anewtonsapple.blogspot.com/p/iron-atoms-and-single-photon-detectors.html

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