Tiny spin waves make particles talk in 2D material.

"Rendition of the discovery where the excitons (e-h pairs) interact via ripples in the magnetic structure akin to an array of spinning tops generating a wave that affects each other and couples the excitons. Credit: Visakh Menon, edited" (ScitechDaily, Tiny Magnets, Big Potential: How Spin Waves Let Particles “Talk” in 2D Materials)

"This breakthrough allows excitons (electron-hole pairs) to influence one another indirectly, like objects disturbing water. The interaction, demonstrated in a magnetic semiconductor called CrSBr, can be toggled on and off with magnetic fields, opening doors to revolutionary technologies like optical modulators, logic gates, and especially quantum transducers for future quantum computers and communication systems." (ScitechDaily, Tiny Magnets, Big Potential: How Spin Waves Let Particles “Talk” in 2D Materials)

The spin waves can be used to control particles. And make them exchange information. This technology can be the new wave of miniaturized technology. That technology can make it possible to connect high-power computing with other structures in spacecrafts and miniature vehicles. 

That means spin waves can make it possible to create new and ultra-thin microchips. Those ultra-thin nano-technology-based microchips can be necessary for tools that must resist extremely high accuracy. 

That thing can be useful in the new types of high-accurate intelligent ammunition. Those ammunition recognize the target using small computers. They will be more accurate and immune to the GPS jamming systems that "Dart" ammunition. But they require new types of thin microchips and mass memories. 

Tiny spin waves make particles talk in 2D structures. That thing means that. Those intelligent 2D structures can sense the impact's strength. A

nd things that pull them. This kind of thing allows the system to detect touches using those 2D materials. And that makes it possible to use them as kinetic sensors. 

Another thing is that the 2D material network that can surround things like satellites and tanks can feel meteorites and ammunition that hit that structure. 

Even if the sensors are on the layer in asymmetric square-shaped order the ability to share information makes it possible for those systems to can detect the place where something hits the surface. That thing can be the sense of touch to the system. 

The same technology can make a new type of quantum sensor. That can be used in joysticks and other things like robot's artificial kinetic sense. 

Modern joysticks operate in that the connector scrubs the carbon layer. 

The carbon layer can pass away. And that makes joysticks unable to be used. And the laser LED measures the bottom's distance to the mirror or straight layer. 

Those LEDs can use triangular measurement where the system calculates triangles and cut triangles to measure the distance. When the mirror is straight the triangles that those laser sensors make are full. When another side of the mirror or black layer turns down the laser system sees that the laser points turn away from each other. The system calculates the distance of those points and sees the tilt angle.

The problem with those systems is that they are too big for nanotechnology. The nano-size robots require new types of systems that can fit inside them. And where those robots can produce enough electricity. The nano-sized robots. That can operate independently in the human body and can revolutionize medicines. Those systems require new types of logical gates and other components.