Nanodiamonds, pressurized atoms, and organic lasers revolutionize quantum computing and quantum networking.

  Nanodiamonds, pressurized atoms, and organic lasers revolutionize quantum computing and quantum networking. 

The new miniaturized microchips require small lasers to be effective. In those microchips lasers and photons replace electrons. And in photonic microchips temperature stays lower, and oscillation is easier to control than in electric microchips. It's possible that in a photonic binary microchip two lasers. When only one laser is on, the value is zero. When two lasers transmit data, the value is one. But the third laser makes this system a simple quantum system. 

In that model, one laser tells to system if it's on. And the value of this laser is zero. Then two other lasers determine if the simple qubits state one or two. This kind of simple system can make it possible to create small and effective computers for miniature systems. 

"Advancements in quantum networking have been made by stretching diamond films, enabling quantum bits to function more effectively and with less expense, marking a significant step towards practical quantum networks." (ScitechDaily.com/Stretching the Limits: How Diamond Manipulation Enhances Quantum Bits)

The new miniature lasers can used in miniature acoustic systems for making sound. The laser can oscillate the membrane straight or the system can aim to liquid between the membrane and the laser. These kinds of systems can used to transport nanomachines. 

In quantum computers, the diamonds can make the next step in the quantum networks. The photon or electron will trapped between cone tips. Then the side-coming laser ray will transmit data to the first photon. Then the system puts those photons or electrons oscillate in the same frequency. Then data will transfer to a higher energy photon or electron. 

"Scientists have made a pivotal advancement in creating compact laser technology using organic semiconductors. This development promises diverse applications, from enhancing OLED (Organic Light-Emitting Diode) displays to aiding in disease detection and environmental monitoring. The new laser, which emits green light in short pulses, overcomes the traditional need for an external laser in organic semiconductor lasers." (ScitechDaily.com/Laser Leap: Organic Breakthrough Lights Up the Tech World)

The system can drive data to the pressurized atom layer, which acts as mass memory. Those atoms may be between diamond cones that transport data to them. That next-generation mass memory can act like a net eye. Each unit in its entirety can store its part of the data. Data stored in that system is like a network. 

This kind of mass memory is required in self-learning machines. The self-learning machine transfers data to the memory and makes a database. Each atom in this advanced data storage can be one table. Then the system will interconnect those tables with each other and the tables, stored in long-term memory. That allows the system to connect stored data with fresh data that come from sensors. 

"Artist’s rendering of a 2D material strategically strained to lie precariously between two different crystal phases. Assistant Professor Stephen Wu from the University of Rochester is using such materials to create hybrid phase-change memristors that offer fast, low-power, and high-density computing memory. Credit: University of Rochester illustration / Michael Osadciw" (ScitechDaily.com/Atoms Under Pressure: The Dawn of Ultra-Efficient Computing Memory)

Because there are lots of tables in those databases. It makes it possible for that system to store data with high accuracy. That accuracy is required for sophisticated memory storage and a highly accurate learning process. When a machine learns it interconnects databases and tables together. Where lots of details are stored in new entirety. This connect accuracy determines how sophisticated the solution is. And if the system connects tables from different databases straight together. That allows the system to store data with high accuracy. 

The best way to work in networked database solutions is to keep the information that the system stores in each tablet at a minimum level. The reason for that is damage in tablet doesn't have a big effect on data entirety. 

The system stores the minimum data mass in each table. But there are lots of tables. And that thing means that if one table faces damage that minimizes damage, and that is one reason why humans have so many neurons. 

https://scitechdaily.com/atoms-under-pressure-the-dawn-of-ultra-efficient-computing-memory/

https://scitechdaily.com/laser-leap-organic-breakthrough-lights-up-the-tech-world/

https://scitechdaily.com/stretching-the-limits-how-diamond-manipulation-enhances-quantum-bits/