AI and quantum computers are the ultimate combinations.

Why cosmic superbubble's magnetic fields are interesting? The answer is that the common magnetic field determines the border of the local cosmic bubble. But the common magnetic field and certain energy levels determine the quantum system. 

One of the things that can determine the quantum system is the certain energy level or the state of the participants of the quantum system. Or we should rather say that the thing that determines the quantum system is that it's the group of participants that can exchange information with each other. 

When we want to make things like a quantum computer. We must bring information from outside to the quantum system.  If we cannot make that thing the quantum computer is useless. Same way, if the errors that a quantum computer makes cannot be detected and correlated, that makes quantum computers useless. 

In some visions, the nanotechnological computer that is put into orbit in the LHC (Large Hadron Collider) can use to make the error correlation and error detection for quantum computers. 

The idea is that the time dilation makes the binary system operate the same way effectively as the quantum computer. Benefiting the time dilation means that the time dilation makes the time move slower in the fast-moving computer. And that gives more time for the calculations. 

One of the most problematic things in quantum computing is error correlation and error detection. Quantum computers are the most powerful computing systems in the world. And that thing means that the only thing that can detect errors in quantum computers is another quantum computer. 

Another problem with quantum computers is that they require superpositioned and entangled particle pairs. The problem with quantum entanglement is that it requires that another side of that thing is at a higher energy level. If the energy level in quantum entanglement reaches stability that destroys the superposition. 

Information cannot travel in quantum entanglement if its energy level is stable. That's why the system cannot keep quantum entanglement longer time. The quantum entanglement exists for about ten seconds. Then the system must re-adjust itself. The AI can observe the quantum entanglement and when its energy level turns stable. It can drive information to mass memories. 

The AI can use for error-detecting. The idea is that when the quantum computer operates for a couple of seconds it can transfer the answer of the calculation to the binary mass memory. The binary system can check part of the calculation series in bites. So the system benefits from the adjustment moment of the quantum computer. And then it makes the bite of calculation. 

In some very futuristic ideas things like time dilation can use in binary systems, and they can check the results that quantum computers are making. The idea is that time is dilated in binary systems. In some visions, the miniature computer that is closed in the nanotechnical capsule will be put into orbit in the LHC (Large Hadron Collider of the CERN).  

New artificial intelligence-based systems can revolutionize everything. When the Ai use to tame quantum systems the idea is that the AI can control individual components in the quantum system. Or actually, the AI can search the quantum system. 

And then, it records the interaction values between outcoming energy and the quantum system's internal energy. When we look at things like quantum computers. We must remember that if we want to control quantum systems. We must bring energy from outside to the system.

And we must make that thing precise in the right point of the system. If the point is wrong, outcoming energy doesn't give wanted value. And that thing destroys the quantum system. The system's destruction means. That it doesn't make anything that the users want. 

The thing that machine learning makes in that kind of research is that it records energy levels and points that give wanted values in the longest possible time. So the AI can adjust the energy level and the point of incoming energy. That is brought to the quantum system very accurately. 

https://scitechdaily.com/groundbreaking-3d-map-of-cosmic-superbubbles-magnetic-field-unveiled/

https://scitechdaily.com/using-artificial-intelligence-to-tame-quantum-systems/

https://shorttextsofoldscholars.blogspot.com/

Quantum computers can find dark matter.

"In a new breakthrough, scientists at the U.S. Department of Energy’s Fermilab have found a way to detect dark matter using quantum computers." (ScitechDaily.com/U.S. Dept of Energy Breakthrough: Detecting Dark Matter With Quantum Computers)

1) How do quantum computers detect dark matter?

The idea of quantum computers is that they use very highly controlled superpositioned and entangled photonic qubits. The idea is that the system pack information photons. And then that photon will be superpositioned and entangled. If that superpositioned and entangled photon touches something. 

That "something" causes a disturbance in the energy level of that superpositioned and entangled particle pair. So if the superpositioned and entangled qubit touches the dark matter. That thing causes disturbance of the energy levels. 

2) What the dark matter could be? 

Dark matter is interesting. 85% of the material in the universe is formed of dark matter. That is the gravitational effect whose source is unknown. The thing that makes the dark matter interesting. Is that it can interact with visible material only by gravitation. There are galaxies there is no dark matter. And that tells that it can form similar clouds as visible material. But what is dark matter? 

There are a couple of theories about that thing. 

*Is dark matter a so-called black photon?

The idea of black photons comes from the idea that the Schwinger effect that formed all matter during the Big Bang forms two particles. Schwinger effect forms particle-antiparticle pair. So the photon should also have anti-particle pair. That "anti-photon" should be a so-called "black photon". 

*Dark matter is virtual material. 

The term "virtual material" means that dark matter could be some hollow quantum field. That quantum field can be a 2-dimensional energy ring that causes forming of a virtual black hole in that ring-shaped structure. That thing explains why it's so hard to detect. 

There is a possibility that also hyper energy photons or some unknown very heavy but small particles are forming that mysterious dark matter. That particle could be like Higgs Boson. But it could exist only small moment. And when that particle vaporizes, it forms the thing called dark energy. 

So in this model dark energy and dark matter have the same source. But where that hypothetical vaporization happens? Does it happen in the plasma of the universe or outside the plasma bubble that is called the universe? 

*Dark matter is extremely high and low energy particles. 

The idea is that dark matter can be so high-energy level particles that they are pushing all radiation away from them. That makes those particles act like stealth aircraft. When wave motion travels or flows over them that causes the situation that there is no reflection from that matter. 

In the low energy model, the dark matter is simple flat material. The energy level of that material is so low that it cannot react.

*Dark matter is quantum-size black holes. 

There is the possibility that dark matter is quantum-size black holes or mysterious graviton particles. If that model is true that explains why we cannot see that particle. In that model, the whisk-looking structure of elementary particles would form at the surface of the magnetic field of that extremely small particle. So the quantum-size black hole hovers in the middle of the quark. 

https://scitechdaily.com/u-s-dept-of-energy-breakthrough-detecting-dark-matter-with-quantum-computers/

https://miraclesofthequantumworld.blogspot.com/