The central part of the experiment in which the coherent matter waves are created. Fresh atoms (blue) fall in and make their way to the Bose-Einstein Condensate in the center. In reality, the atoms are not visible to the naked eye. Credit: Scixel. (Phys.org/Physicists build an atom laser that can stay on forever)
The laser rays can use to create a room-temperature operating quantum computer.
When we are talking about the quantum computers that can operate at room temperature we can use simple two laser rays. The laser ray number one will transmit the qubit layers or sates zero and one (0 and 1). And the second laser is transmitting states or layers two and three (2 and 3).
Laser number one is determining if the computer is on. If the laser number one is on the value is one. If the laser number one is closed the value is zero. The information travels in laser ray number two where that laser hovers the information between states two and three.
The new atomic lasers that can stay on forever can open the road to more powerful quantum and regular computers.
The new atom laser can make the virtual version of the time crystal where energy orbits in the quantum field forever. In that system, the superconducting circuit is making possible for the energy surrounding this system. What makes it possible for that new laser that can be on forever.
This type of laser can make it possible to create a new type of photonic microchips. One version of the use of that kind of laser in data transportation is that the quantum state of the computer sends qubits as photons through those laser rays. Also, a binary system can send photons through those laser rays.
The next-generation plastic-based microprocessors can use those atomic lasers for information transporters. The system can be more powerful than we even imagine.
The new atomic lasers can use in quantum memory. Those new memory units can be the bites of plastic where laser rays are jumping between 100% reflecting mirrors. When that data is needed the crossing laser rays will just shoot through those laser rays.
The atomic laser that can be on forever can make it possible to make very fast photonic microprocessors that can operate in very low temperatures. And those microprocessors can operate in the next-generation spacecraft that operates in the Kuiper belt and farther.
The ability to interconnect two-time crystals makes it possible to use them in the next generation of superconducting microchips.
Connecting time crystals makes it possible to use them as wires in small superconducting quantum computers. That thing along with new memristors and other components can make it possible to create a new type of system that can be more fundamental than ever before.
In time crystals the row of atoms wobbles back and forth. And in that strange entirety, the energy rotates in quantum structure. This means quantum crystals recycle all energy that they use in that wobbling movement. This thing makes those time crystals quantum-size perpetual motion machines.
And if the microchip uses time crystals as the wires that kind of system requires very little energy. If the time crystals are used as the wires in the microprocessors. That thing makes it possible to create superconducting atom-size quantum microprocessors.
In that system information package will be shot at the end of the wobbling atom line in the form of a photon. The information that travels through that extremely cold superconducting atom line will keep its form. And when that information package travels through the time crystal. It turns back to the photon.
The photovoltaic cells or photometers are detecting the brightness or energy level of that photon. This system needs those photovoltaic cells to transmit data from the superconducting quantum system to the regular computers that are giving orders to the motors that control the movements of robots.
And those kinds of systems are perfect tools for superconducting microchips. The problem with those ultra-fast computer tools is that the electricity jumps over the switches. The time crystals are perfect tools to capture energy from the plasma. They can operate only at extremely low temperatures.
https://www.msn.com/en-us/news/technology/physicists-link-two-time-crystals-in-seemingly-impossible-experiment/ar-AAYvfTw?li=BBnb7Kzhttps://
https://phys.org/news/2022-06-physicists-atom-laser.html
https://phys.org/news/2022-06-physicists-qubits-laser.html
https://www.techradar.com/news/rip-expensive-silicon-chips-plastic-processors-are-the-future
https://en.wikipedia.org/wiki/Memristor
https://en.wikipedia.org/wiki/Time_crystal
https://miraclesofthequantumworld.blogspot.com/
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