In modern quantum computers, the information can travel in two-layer nanotubes. Between those nanotubes can travel the laser rays. The laser rays are making it impossible to reach the information that is traveling in electrons or photons inside the nanotube. The hollow laser rays can also protect information that is sent through air by using the qubits.
The fact is that nanotechnology allows the creation of quantum systems where information travels with warp speed. In that model, the plasma whirl that is in the layer between two-layer nanotubes isolates the internal nanotube from the outside. That thing forms the electromagnetic wormhole where photons and electrons are traveling faster than in a free universe.
Quantum cryptography.
The base and virtual model of quantum cryptography is that system cuts messages into pieces. And then that system sends those pieces at the same time, using different frequencies. If those pieces follow hierarchical protocol. There is one mistake that can help to break the message. And that is sending the next frequency in the message.
In that kind of encryption, sending system will cut the message into pieces or segments. Then each message's segment will equip with a serial number so the receiver can put those pieces in a certain order.
Except in one case but that requires a mistake from the sender. If the hacker can get the first message in the hands. This thing makes it possible to follow the route. In a hierarchical model, each piece or segment of the message contains information on what frequency the next part of the message uses.
But the fact is that real encryption specialists are not sending any message that involves the code key. There is a possibility that there are multiple internal algorithms. That is hiding and securing the message.
The pieces of the message can send in simultaneous bursts and the system can mix their order. If the encryption system will count some numbers to the code that tells which order the receiver must put those bites of the message that makes it almost impossible to crack those messages.
The secrecy level can rise when the content of each message's segment is encrypted by using different prime numbers. The encryption can contain so deep process that each mark of those segments is encrypted with an individual decimal prime number.
Real quantum cryptography is impossible to break because data is packed into photons or electrons. The data can travel in the nanotubes there it is protected by using laser rays. So the outsider cannot reach the message itself.
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https://scitechdaily.com/making-hacking-futile-quantum-cryptography/
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