"Artistic image of the new inspection tool for ultrafast electronics with femtosecond electron beams. Credit & Copyright: Dr. Mikhail Volkov, edited" (ScitechDaily, Bridging Realms: Unveiling the Future of Electronics at Terahertz Speeds)
New photonic microprocessors are faster than nobody expected. The photonic microchips along with femtosecond electron beams make it possible to create a new way to make microchips. And that brings a new way to create fast and secured long-distance data transmissions. But those microchips are so fast that we can say that Moore's law is broken in the photonic networks. The speed of photonic networks and photonic processors is so high. That makes those systems faster than regular processors.
Even if there are fewer transistors in the system. The difference between photonic, and electric networks is that photons don't cause so much heat, and because photonic processors can use double frequency in light, that makes it independent from clock frequency. In double ray systems the "zero" problem or how the system separates zero from shutdown solved using two laser rays.
If data travels in a binary photonic processor in red and blue laser rays, the red laser ray can give the value of zero (0). And blue laser light can give a value of one (1). The system can give serial numbers for those bits, and then the AI-based kernel can sort them in the right order when those bits travel through processors.
"Lightmatter, a company founded by MIT alumni, is pioneering the use of light for data processing and transfer to address the limitations of traditional computing methods. (Artist’s concept.) Credit: SciTechDaily.com" (ScitechDaily, Breaking Moore’s Law: Lightmatter Accelerates Progress Toward Light-Speed Computing)
Those laser rays give zero and one to the system. Another way is to use a different computer that tells the other system when electricity is turned off.
Those photonic microchips are the most powerful tools for the portable computers. And they can help to operate quantum computers. But the thing is that the phonic processors fall the Moore's law. They can bring new power to the mobile systems as well as to central supercomputers. The new powerful supercomputers can control the quantum computers. But those systems can operate in stages. First, the binary computer tries to solve the program.
The film above tells how electricity travels in wires. Superconducting means that the Hall fields or crossing fields that cause resistance are removed. The low temperature causes the effect. That atoms turn very close to each other.
And in the ideal case, their quantum fields turn into tubes. But there is no ideal world. The crossing electric fields that impact around wires form wave that travels opposite ways to the main electric flow. And those opposite traveling waves sucking the power of electricity. Those waves also disturb data that travels on the wire.
"The bright spheres symbolize bound charge carriers (negative and positive) in the material. The light beam separates these charges, which are then deflected in different ways in the applied magnetic field. With the CLIMAT (Constant Light-Induced Magneto-Transport) method, around 14 different parameters of the transport properties in semiconductors can be measured with a single measurement, for example, density, lifetime, diffusion lengths, and mobility. Credit: Laura Canil (www.canilvisuals.com)" (ScitechDaily, Unlocking the Secrets of Semiconductors With a Single CLIMAT Measurement)
The quantum computer can now create quantum entanglement through that quantum tube. As you see electricity is not traveling in the wire. And that makes it possible to create the quantum tube over the wire using lasers or microwaves. Those hollow tornado-shaped quantum fields or electromagnetic wormholes can deny the outcoming effects of interaction with qubits. Another way is to create electromagnetic wormholes using nanotubes.
The superconducting microprocessors are also the ultimate tools. The microprocessor requires the AI control. The semiconductor, like silicone, will freeze to the superconducting condition. Then the system changes the processor's temperature. This thing can be impossible to do in real life. And a rise in temperature makes it possible for the processor's material to break.
Chancing temperature in superconducting circuits allows those systems to change their states between quantum and binary states. And that is a big advance in computing.
But in the two-channel applications, the superconducting microprocessors can be very fast. In those systems, there are two processors. One of them handles only one and the second processor handles only zero. This thing can make the superconducting systems more effective.
https://scitechdaily.com/breaking-moores-law-lightmatter-accelerates-progress-toward-light-speed-computing/
https://scitechdaily.com/bridging-realms-unveiling-the-future-of-electronics-at-terahertz-speeds/
https://scitechdaily.com/unlocking-the-secrets-of-semiconductors-with-a-single-climat-measurement/
https://en.wikipedia.org/wiki/Hall_effect
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