The new technology boosts quantum computers and quantum stealth systems.

"Researchers at NYU Abu Dhabi’s Photonics Research Lab have developed a new two-dimensional material that can precisely manipulate light, promising enhancements in bandwidth for communication networks and optical systems. This breakthrough in tunable optical materials demonstrates potential applications in environmental sensing, optical imaging, and neuromorphic computing. (Artist’s concept.) Credit: SciTechDaily.com" (ScitechDaily, Revolutionizing Photonics: 2D Materials Manipulate Light With Remarkable Precision)

New technology allows systems to manipulate light with very high precision. That technology allows to creation of new types of stealth systems and new types of quantum computers. The same counterwave technology that operates in stealth systems can protect the quantum computers against disturbance. The 2D quantum surface can create counterwaves that deny electromagnetic radiation reach the quantum entanglement. 

The new fundamental research allows the 2D quantum metasurface can manipulate light with a very high accuracy. The waving 2D metasurface can send counterwaves that can make light unable to reach the surface. Counterwave technology makes it possible to create structures that give minimum or even deny the reflection from the surface. 

If the counterwaves that hit the incoming wave movement have the right power, that denies incoming electromagnetic waves reach the shell. The system must use a model that impacts counterwaves and drives incoming electromagnetic waves in a certain direction. That reflection direction must be somewhere else, where the electromagnetic wave arrives. The system can drive electromagnetic radiation around it. And that denies the sensor to see the object. 

"TU Darmstadt researchers have developed a quantum processor with over 1,000 atomic qubits, marking a significant advancement in quantum computing scalability. This breakthrough could enable the future expansion of qubits to 10,000, enhancing various technological applications." (ScitechDaily, Over 1,000 Qubits Achieved – Physicists Set World Record for Atom-Based Quantum Computers)

When we think about stealth, counter-stealth, and other kind of technical solutions. The compact quantum computers make it possible to control materials by using advanced AI. 

In some models, the regular-looking aircraft can turn stealth if the system allows radio waves can travel through the shell into the center of the craft. Those electromagnetic waves can be collected in the middle of the structure, and then maser technology drives those waves in one direction. That denies the electromagnetic waves' reflection into the sides of the structure. But the ability to manipulate light makes it possible. That the system could theoretically turn invisible to the human eye. 

The new 2D materials allow to creation of new types of quantum computers. The system can take atoms in the net of 2D material. Then the system pushes those atoms in flat form. After that, the system makes the quantum entanglement between electrons that the system presses into a layer, and drives a laser beam in those trapped atoms. Those structures allow the quantum computer can create qubits with even billions of states. 

"In a large quantum system comprising many interconnected parts, one can think about entanglement as the amount of quantum information shared between a given subsystem of qubits (represented as spheres with arrows) and the rest of the larger system. The entanglement within a quantum system can be categorized as area-law or volume-law based on how this shared information scales with the geometry of subsystems, as illustrated here. Credit: Eli Krantz, Krantz NanoArt" (ScitechDaily, How MIT Is Redefining Quantum Computing With New Entanglement Control)

A key element in quantum computing is how to drive information into particles, which the system should put into superposition and entanglement. The quantum computer is useless if it cannot drive information into those particles. 

The new way to make the quantum entanglement makes it possible for the quantum systems can interconnect qubits in the 3D structures. The system is a network where the system can maintain quantum entanglement for a longer time than before. 

The system uses technology where the receiving participants in quantum entanglement can push information into another particle before quantum entanglement reaches the same energy level. If the system can create a structure where quantum entanglement can jump between quantum dots, that thing is the biggest breakthrough in quantum technology. 

https://scitechdaily.com/how-mit-is-redefining-quantum-computing-with-new-entanglement-control/

https://scitechdaily.com/over-1000-qubits-achieved-physicists-set-world-record-for-atom-based-quantum-computers/

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