“Scientists from the University of Technology Sydney have demonstrated that quantum signals can be transmitted upward from Earth to satellites (Artist’s concept). Credit: SciTechDaily.com” (ScitechDaily, Thought to Be Impossible: Scientists Show Quantum Light Could Be Beamed Up to Space)
Researchers send quantum light to space. And that can open the path. To the new types of secured satellite communication. Another thing is that quantum light can also make it possible to create a wireless quantum network. This can make communication more secure. The secured communication means that outsiders cannot eavesdrop. Those systems. And that makes it possible. To create wireless communication. That can be used to control things in orbit. The system can transmit information to the relay station. That spreads it into all kinds of systems that can communicate with that relay station. The term quantum light describes light as photons. Quanta of energy. This means the system can benefit one or more. Those things are used to transmit information.
And the wave-particle nature of light. Quantum light information can travel in the chain of superpositioned and entangled photon lines. Quantum light can also mean. A mixture of the laser beams. Those laser beams are entangled internally, and the light that seems white involves thousands of coherent light beams. This is one version of the quantum light. The ability to send quantum light to space means the possibility of communicating. With satellites. More secure. As I wrote earlier. The quantum light can also operate. As a thermal pump. That decreases the temperature in some structure.
But this technological success requires that the light. Or photons can sustain information. That is stored in them. If that is possible someday. That is the greatest possible advance in wireless communication. As we know, quantum is much more than just quantum computing. Its materials, communication, and many other things. It's the system that can control energy flows.
Meissner effect or superconducting levitation.
"Josephson junction structures—quantum devices made of two superconductors and a thin non-superconducting barrier—using different forms of germanium (Ge): super-Ge (in gold), semiconducting Ge (in blue), and super-Ge on wafer-level scale. Millions of Josephson junction pixels (10 micrometer square) can be created with this new material stack on wafer scale. Inset shows crystalline form of Super-Ge on the same matrix of semiconductor Ge, a key for crystalline Josephson junction. Credit: Patrick Strohbeen/NYU" (ScitechDaily, What Happens When a Semiconductor Becomes a Superconductor?)
A large number of superconducting cylinders can levitate even large structures. The Meissner effect can make it possible to create a new and revolutionary transportation system.
"At the low temperatures required in quantum devices, strontium titanate crystals (purple atom and bipyramids) let electric fields sculpt light fields (blue) orders of magnitude better than any other material. Credit: Second Bay Studios" (ScitechDaily, “We Made the World’s Best Material” – How a Diamond Substitute Could Revolutionize Quantum Computing)
"Physicists use a new platform to measure magic-angle graphene’s superconducting gap. The method involves “tunneling” electrons between two layers of magic-angle twisted tri-layer graphene (in yellow) while measuring the material’s superconducting state. The team’s experiments are the first to show clear evidence that MATTG is an unconventional superconductor. Credit: Pablo Jarillo-Herrero, et al." (ScitechDaily, MIT’s Magic-Angle Graphene Just Changed Superconductivity)
Today. That levitation can be possible as long as there is liquid nitrogen and iron powder. But making those systems real. The system requires the superconducting magnets. There is a possibility. To put the system on hold. Using the ultra-cold iron powder and the liquid nitrogen. That keeps magnets at a low temperature. The system could also inject that liquid nitrogen under the vehicle. But those systems are far from operational systems.
Superconductors are one of the quantum states of matter. There are two ways. To make superconducting supercomputers. In the first model, the entire system is superconducting. In the second model, only the wires are superconducting. One of the most fascinating possibilities is the semiconductors. That can switch between semiconducting and insulating materials. The electron flipper in the materials can transport energy out of the system. In the direction where the controller wants. The electron pinball transports energy out from the thermal centers.
Things like superconductors can revolutionize computing. Transportation. And many other things. Superconducting levitation is one of the things. That can be used in the next generation of transportation systems. The ability to control the superconductors by switching the superconductor on and off. It can make it possible to create the hovering vehicles that are even more exciting than some quadcopters.
If we think of the empire’s speeder bikes and scout vehicles in the Star Wars movies, the superconductor that can work in high temperatures can make that system possible. Superconducting systems can make it possible to replace the quadcopter rotors. By using the superconducting magnets. Maybe. That system could also. Make the wingless aircraft. With ultimate vertical take-off and landing capacity (VTOL). Along with ultimate stealth capacity.
The superconductor can make the system levitate. And the small jet engine. Can make those systems fly at high speed. It is also possible that the famous “Black Triangle” vehicles can be used for their silent levitation. The superconductors are used to levitate. In the levitation systems, the superconductor. That is in the vehicle itself. It can make it possible to create new types of transportation vehicles.
The magic angle graphene and other 2D materials can transport heat out of the structure without standing waves. Laboratory-grown diamonds can make the new types of coolers possible. Those systems can hang artificial nanodiamonds between graphene layers and then conduct airflow between those layers. The artificial diamond can be used. To pump energy out of graphene. This kind of system can make the dream of compact, high-temperature superconductors. Into reality. But before the room-temperature superconductors, those systems were only a dream. Those materials can also make it possible to create the ultimate-fast aircraft and shields that can protect systems against mechanical and laser impacts.
https://www.researchgate.net/figure/Passive-magnetic-levitation-Levitating-permanent-magnet-above-an-YBCO-superconductor_fig2_335995569
https://scitechdaily.com/mits-magic-angle-graphene-just-changed-superconductivity/
https://scitechdaily.com/physicists-discover-bizarre-quantum-pinball-state-of-matter/
https://scitechdaily.com/thought-to-be-impossible-scientists-show-quantum-light-could-be-beamed-up-to-space/
https://scitechdaily.com/what-happens-when-a-semiconductor-becomes-a-superconductor/
https://scitechdaily.com/we-made-the-worlds-best-material-how-a-diamond-substitute-could-revolutionize-quantum-computing/
No comments:
Post a Comment
Note: Only a member of this blog may post a comment.