The quantum breakthrough. (Entangled Photons Transmit Without Interruption for 30+ Hours)

 "Oak Ridge National Laboratory collaborated with commercial utility EPB and the University of Tennessee Chattanooga to develop and test the first transmission of an entangled quantum signal using multiple wavelength channels and automatic polarization stabilization over a commercial network with no downtime. Credit: Morgan Manning/ORNL, U.S. Dept. of Energy" (ScitechDaily, Quantum Networking Breakthrough As Entangled Photons Transmit Without Interruption for 30+ Hours)

The ultimate quantum simulation. The system sets a record in quantum entanglement data transmission. And that is a breakthrough in quantum network research. In tests, the qubits transmit information for 30+ hours. And that can be the step to scalable quantum networks and new types of quantum computers. The advances in this technology are fast. Quantum computers and AI are the ultimate combination for the next-generation quantum systems.

In those systems, the AI controls the behavior of the qubit in every situation. The AI also collects datasets that quantum systems can use to predict the behavior of the qubits. The scalable quantum network requires all data from the systems and environment. By using that data it can create precisely similar qubits to other systems. Maybe the other quantum computers stay in the computer centers for a while. 

But they follow the advancement of regular computers. The first computers were not very simple to use. They were very large and impractical. Today we have mobile telephones, with more memory and capacity than some 1980s supercomputers. The computer came from industrial halls to pockets faster than people predicted. 

 

 "The quantum network technology using automatic polarization compensation developed by ORNL was demonstrated in Chattanooga, Tennessee. The test utilized EPB’s fiber-optic commercial quantum network and involved the University of Tennessee Chattanooga and industry partner Qubitekk. Credit: Joseph Chapman, Morgan Manning/ORNL, U.S. Dept. of Energy" (ScitechDaily, Quantum Networking Breakthrough As Entangled Photons Transmit Without Interruption for 30+ Hours)

(ScitechDaily, Quantum Networking Breakthrough As Entangled Photons Transmit Without Interruption for 30+ Hours)

 

"A newly developed quantum simulator merges digital and analog techniques, vastly improving the ability to model complex systems. With applications ranging from material science to black hole research, this advance opens new doors in computational physics. (Artist’s concept.) Credit: SciTechDaily.com" (ScitechDaily, Quantum Computing Breakthrough Brings Us Closer to Universal Simulation)

The quantum networks can make ultra-secured data transmission possible. The same technology that collects data for some activity wristband can also connect human nervous systems together. That creates the ultimate neurocomputers that can connect people together and make new types of cooperation between humans and machines possible. But those systems require ultra-secure data transmitting. The system can make contact with hand nerves. And it can make new types of systems possible.

The intelligent wristwatch can have more memory than the supercomputer in the early 1980's. In the same way, quantum computers come from industrial halls under people's desks faster than we predicted. About two- or three years ago the quantum entanglement remained about 30 seconds. Today that time is about 30+ hours without disturbance. And it makes this kind of system more powerful than ever before. Quantum computers and AI-based networks are tools that accelerate the advancement of those systems.

The quantum simulation helps predict the behavior of the qubit in certain situations. That means the quantum computer can predict situations where the qubit is breaking. Or actually, the AI that controls the qubits makes that prediction. If we think that quantum entanglement is made between photons. That is trapped in the atom's quantum fields that kind of system is quite sensitive to things like gravitational waves.

For controlling the system the controller must get all data from it. That means there are more things than just heat that can destroy the quantum entanglement. In quantum systems, data travels between superpositioned and entangled photons. The system loads information to the photon. Information itself is in the form that looks like a little string. The system sends that quantum string to the quantum channel between those photons.

If a gravitational wave changes the direction of those photons that can cause catastrophe. The high-accurate atom clocks and new types of gravitational wave detectors can be answers to the problems that quantum computers face. The heat is the main thing that destroys the quantum entanglement. When the energy levels in both ends of the quantum entanglement, or "quantum stick" rise to the same level, that breaks the entanglement.

When the system predicts the behavior of the quantum entanglement it compiles the dataset collected from other systems. And when it sees a situation where something disturbs the quantum entanglement it can store data in backup memory. The system must make backups all the time because things like changes in gravity fields or some electromagnetic disturbance can destroy the quantum entanglement.

https://scitechdaily.com/quantum-networking-breakthrough-as-entangled-photons-transmit-without-interruption-for-30-hours/

 https://scitechdaily.com/quantum-computing-breakthrough-brings-us-closer-to-universal-simulation/