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Beyond Moore's law: how to make more powerful computers.

    Beyond Moore's law: how to make more powerful computers. 


The main problem is how to keep the temperature in the computer system low. 


Moore's law means that the number of transistors in microprocessors grows exponentially in time units. Or otherwise saying the number of transistors will double every year. Moore's law is not reality anymore. The reason for that is when the size of microprocessors and transistors is getting smaller, quantum phenomena like electromagnetic whirls cause problems. The resistance raises temperature which causes oscillation in wires. And that oscillation is the thing that disturbs high-power data transmission. 

The reason why the researchers wanted to keep the size of microchips small is that long wires cause temperature problems and the electromagnetic turbulence and outside electromagnetic effects are causing more problems for microchips than short wires. And that's why a small microchip is less vulnerable to outcoming radio interference than large-scale microchips. 



Above: A supercomputer center




Above fullerene nanotube. But that image could portray EMP-protected wire that is in a Faraday cage. 

How to remove the electromagnetic oscillation and outside EMP effect from computers? 


The EMP protection allows to use of larger-size microchips and high-power coolers can stabilize the wires. Reseachers must cover every single by using a Faraday cage, and the system must keep their temperatures low. 

But one version to remove the outcoming effects is to use the EMP-protection in the wires. The image that portrays a fullerene nanotube can portray EMP-protected wires. Those wires would be closed in a Faraday cage that removes the electromagnetic effect from those wires. 

1) The microchip's size can turn bigger. Making bigger microchips with high-power cooling systems makes it possible to create microchips that have more transistors and diodes than existing microchips. 

The advanced cooling systems can keep the temperature low. However, those microchips can be suitable only for supercomputer centers. Those large-size microchips require EMP protection and advanced cooling systems. And that's why they are not suitable for home computers. 

2) The system can use photonic computing. In photonic computers, the laser rays are replaced by regular copper wires. The laser transmits data to the small-size light- or photovoltaic cell. And that silicon crystal turns flashes of light into zero and one. Photonic computers can keep their temperatures lower than regular computers. 

3) The third method is to control the system more effectively. The AI-based operating systems can keep the temperature in the microchips optimal. And that means the AI-based systems can share missions between multi-core processors more effectively. In those systems when the temperature rises in one processor, the AI can route the missions into other processors. 

That allows for decreased temperature in those processors. And, of course, the system can share its missions between multiple components. Those components can be independently operating computers even if they are in the same box.  The AI-based network can share its missions also between physical systems. 


https://dailycaller.com/2018/04/09/rick-perry-supercomputers/


https://scitechdaily.com/beyond-moores-law-mits-innovative-lightning-system-combines-light-and-electrons-for-faster-computing/


https://en.wikipedia.org/wiki/Moore%27s_law

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