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The qubits and unbreakable code

 
 

The qubits and unbreakable code

Lasers and qubits

Two lasers can make qubit. Laser-based qubit is very easy to make in theory. The system requires two lasers. The other laser would be used to transfer the message, that if the electricity is on and off. Another laser would send the information and the level of light would be the thing, that transport the signal. When the data transportation laser would send the data by using the level of light, what is below a certain level of candelas(1), that means zero and the level of light, what is above a certain candela level means one. Another laser would transfer only the data if the power in the system is cut. 

There is one thing, what makes qubits so interesting and fascinating tools, and that thing is that qubit can transport information also in the long distances. And why this kind of version of the transportation of information is interesting? The answer is that this kind of code, what is packed in the qubit is unbreakable and the message is unable to read if the qubit cannot be captured, and the message read by using proper systems. But what kind of thing is the capsule, what can transport the message? 

The qubits and unbreakable code

The message itself can be stored in the fullerene, where is the small line of the atoms, what might be in the Buse-Einstein condensate. That means that the data can store in that capsule, and when the system wants to open it, the fullerene capsule must just move to the layer, where the information, what is stored in it would be transferred to the computer. Or the data can store in the DNA, and that chemical data storage can be read as the high-tech punch card. 

If we would send the messages in the form, where it is stored in the nanotechnical qubits, that thing makes it possible to transport information safely and effectively. But of course, the problem is that the time that message needs to travel from one place to another is quite long. And also that kind of capsules need the extremely low temperature to work. But the most confidential messages can be stored in the miniature submarines or some other type of nanomachines, and they can transport the data in the water supply. 

In the pipes of water supply would be installed the station, where the miniature submarine will drive, and then the system will release the stored information to the sensor. The support station would call the submarines to it, and without that kind of system, the miniature submarines are almost impossible to detect. And that makes this system very promising, in theory, but the thing, what limits the use of that kind of system is the low temperature what the superconducting element requires. 

There is, of course, possible to make the hybrid system, which uses laser communication in the message transportation. The data can be stored in the qubit and then the laser system can send the data to the 
target. 


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