The new material can switch superconductivity on and off.

Scitechdaily.com describes new material this way: "MIT physicists have found a new way to switch superconductivity on and off in magic-angle graphene. This figure shows a device with two graphene layers in the middle (in dark gray and in inset). The graphene layers are sandwiched in between boron nitride layers (in blue and purple). 

"The angle and alignment of each layer enables the researchers to turn superconductivity on and off in graphene with a short electric pulse. Credit: Courtesy of the researchers. Edited by MIT News" (ScitechDaily.com/MIT Physicists Discover Way To Switch Superconductivity On and Off in “Magic-Angle” Graphene)

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The new material is graphene which can switch its magic angle. And when those magic angles are in line. Graphene is in superconducting form. When graphene turns its magic angles into nonlinear formation. That will destroy its superconductivity. 

That material can be suitable for next-generation microchips and other kinds of things. Switching the material's mode between superconducting and non-superconducting modes is interesting. That thing can make it possible to adjust the speed of information transfer in microcircuits. So the system can transport information by using a two-speed mode. 

In regular mode, the system can use normal resistant wires. But in cases where the signal needs some special attention or includes urgent information the system can switch to superconducting mode. Using two modes in the microchips makes it possible to adjust the computer's speed. The problem with superconducting microchips is that they need an extremely powerful cooling system. 

So when the computer doesn't need its maximum speed it can use regular binary processors. But when it needs extra power. It can transfer data to the superconducting processors. That material can act as a medium between regular processors that work at room temperature and superconducting processors. 

The superconducting mass memories are very good data storage. And that kind of system can store data very accurately. When the mass memory turns to non-superconducting mode. The system destroys data. So, when the data is driven to that memory, it's in superconducting mode. When the system used that data the memory block can be formatted. And in that process, the system can turn mass memory to resistant mode. 

This new material can make possible to creation of a new type of computer possible. And the ability to transmit information between processors by using two-speed could be useful in neurocomputers. That makes it possible to emulate the human nervous system where urgent messages travel faster than regular messages. 

The quantum computer can be a series of superconducting microprocessors. In that case, the system requires superconducting cables that can transmit information between two microchips. The system contains data handling lines where a series of microchips are acting like virtual quantum computers. In that low-power-, virtual quantum system. The TCP/IP protocol will break the information into pieces. 

And then the AI-based system will transfer that data to another processor group and collect it in the new form. Those low-power virtual quantum computers are more powerful than traditional computers. And the material that can switch between superconducting and resistant modes can be suitable in that system. The resistant mode allows the cleaning of the memory blocks when their data unit is used. And it allows using fast- and regular modes in data transfer speed. 

That ability can make things like neurocomputers more effective. The ability to change the data transmission's speed makes the computer work like the human nervous system. And if the system can send two signals at different speeds. That makes it possible to observe possible errors. 

If the data handling system can send the same signal twice to the same processor. It allows the observation of "black swans" or sudden happening anomalies like some gamma-ray impacts on the data channel. If there are errors in those signals there is some unexpected anomaly in the system. 

https://scitechdaily.com/mit-physicists-discover-way-to-switch-superconductivity-on-and-off-in-magic-angle-graphene/