Two breakthroughs in photonics and quantum entanglement can revolutionize, at least, computing.

"Researchers have created the first Group IV electrically pumped laser, overcoming key challenges in silicon photonics. Operating with low power on silicon wafers, it promises efficient, cost-effective solutions for next-generation microchips. Credit: Forschungszentrum Jülich / Jhonny Tiscareno" (ScitechDaily, Silicon Photonics Breakthrough: The “Last Missing Piece” Now a Reality)

The photonic mass memories can benefit the silicone photoelectric vortex. The laser systems can write data to silicone memory. That can store data in binary form. The laser system just makes electric marks on the silicone cylinder. The only thing that limits the use of that kind of memory is that if something touches the silicone, it can lose its electric load. 

Photonics and high-accuracy laser systems can make it possible to transport data to silicone. And maybe high-accurate laser- and photonics can make new types of memory chips possible. The laser systems keep temperatures low. In the system. And they are less vulnerable to electromagnetic fields than regular electric wires. Photonics is one of the newest quantum technologies. There are lots of uses for those highly precise information transportation tools. 

"An illustration of two entangled molecules which are individually trapped in magic-wavelength optical tweezers. Credit: Durham University" (ScitechDaily, Revolutionizing Quantum Science: The Secret of Long-Lasting Molecular Entanglement)

Another thing. What is interesting is the molecular version of the quantum entanglement. The molecular quantum entanglement offers many possibilities in quantum computing and quantum- and nanotechnology. If we think about the possibility of making the quantum entanglements between carbon chains. That makes the new type of quantum structures possible. 

The Quantum structure with the superpositioned and entangled molecules can aim information precisely in one direction. This makes the new things for things that should resist heat. The quantum entanglement makes it possible to create a structure that drives light waves in one direction. That thing can make new types of materials with the ultimate heat resistance. 

This type of material can make the invisibility cloak possible. The quantum rolls are energy fields between atoms that can aim information in one direction. And that makes a Star Trek-style invisibility cloak possible. The structure drives information through structures in the form of strings. 

"This illustration shows how X-shaped monomers are interlinked to create the first 2D mechanically interlocked polymer. Similar to chainmail, the material exhibits exceptional strength. Credit: Mark Seniw, Center for Regenerative Nanomedicine, Northwestern University" (ScitechDaily, Nano-Chainmail Unveiled: Revolutionary Material for Lightweight, Tough Protection)

The quantum entanglement between molecular structures is a breakthrough. That breakthrough makes it possible for complex systems can exchange information. This makes quantum teleportation between complex systems possible. And maybe sometime in the future, we can transport small robots and other things through the wormhole. 

Photonics and quantum technology can make new intelligent nanostructures possible. The nanostructure there is the nanosensor inside it can feel any touch that touches it. When the carbon or metal chains send an electromagnetic field into the structure. Everything that touches the nanostructure affects those fields. And that makes it possible to create machines that have a sense of touch. The sensor acts like radar that sees any difference in the distances of those layers. 

https://scitechdaily.com/nano-chainmail-unveiled-revolutionary-material-for-lightweight-tough-protection/

https://scitechdaily.com/revolutionizing-quantum-science-the-secret-of-long-lasting-molecular-entanglement/

 https://scitechdaily.com/silicon-photonics-breakthrough-the-last-missing-piece-now-a-reality/