The optic USB-stick gives a new type of data security

The optic USB-stick gives a new type of data security

Transporting the stored light is one of the things, which are opens new opportunities for a new and safe way to store data. The magnetic data mass-storage can read to the computer without the owner of the data storage notices it. And that thing makes those things problematic. If the data is read to some supercomputer it can start to break code. The owner of data that doesn't even know that the data is stored. The USB-sticks are used to transport the highly secured data like cryptic keys to systems.

Those cryptic keys can be the images, that are stored in the encrypted area, and they are used like physical keys to data networks. And if those keys are copied, the hackers can enter the system without nobody notices them.

If we are thinking of traditional or USB-storage what can be encrypted, the problem is that the similar systems, what are observing the neural electricity of the brains can read the bits that are stored in the USB sticks. Those systems are basing the superconducted antenna and extremely sensitive technology. So when the encrypted data is read to the computers, the code-breaking computers can start to operate with that.

That kind of system, what reads data from the USB-stick can be in the customs or it can be even portable, and the data from USB-memories can read that the victim doesn't even notice that thing. So the stored light could solve the problem. If that thing doesn't require the external energy, this is the revolution of the data systems.

The optical USB-stick could be basic like a thermos bottle, where are mirrors, and the laser ray will jump between those mirrors. When the data is read to the computer it is lost from the stick. And the owner notices that the data is lost.

Researchers have created a way to make an echo of the 100% of the light. This thing requires that the mirror is cooled to the zero Kelvin degrees, which makes that mirror stable. And if the system uses very small or nano-size mirrors that help to keep the surfaces of mirrors stable. That means that we could stop the laser ray between mirrors, and store the data to that light. When the system needs to access in that data the laser ray simply turn to affect the light cell, and then the data is transferred to the computer.

By using nanotechnology there is a possibility that researchers could create the USB-stick-size thermos bottle, where is extremely small mirrors, where the laser ray is jumping between those mirrors. The thing is that the extremely small size of the mirrors is making the system stable enough. And when the data is needed to read, the mirror just lets the laser ray enter the computers.

https://phys.org/news/2020-10-physicists-successfully.html

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