Light-induced superconductors can be the key to next-generation computers.

"Mid-infrared laser pulses coherently drive atomic modes in YBa2Cu3O6.48 and stabilize superconducting fluctuations at high temperature. This quantum coherence leads to the ultrafast expulsion of a static magnetic field. Credit: S. Fava / J. Harms, MPSD" (ScitechDaily, Light-Induced Superconductivity: A New Frontier in Quantum Physics)

Light-induced superconductor means that the system can adjust superconductivity using laser rays. The researchers can connect the laser system with the regular superconductors. In that case, the laser ray just warms the wire and removes superconductivity when the user wants. The AI-controlled laser system can operate with very high accuracy. And that means the wire can be at the border of the superconducting temperature. Then the laser system raises the temperature by about a couple of degrees. 

That thing can form the resistor in the superconducting wire. And that kind of system can make it possible to create superconducting computers. The problem with superconducting computers is the resistors and other kinds of components like switches. The superconductors don't cause resistance. That thing causes problems, with the superconducting computers in the systems that must control the data flow. 

The superconducting computers are ultimately fast, but the problem is how to control data flow. Miniature superconducting computers require extremely low voltage. If the system can cut the superconducting state. When it is needed at a precise point, that can be the revolution in computing. 

Photonics creates the theoretical possibility of creating quantum computers and other devices. That can make a revolution in computing and material research. The quantum entanglement between hovering photons above the material can be the thing that makes the new waves to quantum computing and quantum networks. The other physical shell can protect information that travels in that quantum tunnel. 

But the most interesting thing that photonics can make is the superconducting material that is superconducting a room temperature. The idea is that the photons press from both sides of the material like a hydraulic press. That thing makes it possible to create a material that can be superconducting because of pressure. 

The high-pressure system can turn wires superconducting by stabilizing those atoms. That means a high-pressure system can make room-temperature superconducting systems possible. There are two ways to make the pressure. The liquid in nanotubes can act as a stabilizer. Or the laser system can make the pressure. 

The quantum systems require a new way of thinking. Quantum computers require powerful support systems. If we want to make quantum computers that operate at maximum speed and power, the bottleneck is the other systems like input-output tools. The quantum computer is a tool that requires high-power AI-based operating systems that can react very fast. 

https://scitechdaily.com/light-induced-superconductivity-a-new-frontier-in-quantum-physics/

https://scitechdaily.com/revolutionizing-photonics-2d-materials-manipulate-light-with-remarkable-precision/

https://scitechdaily.com/transforming-light-how-novel-photonic-shapes-advance-optical-technologies/