The quantum computer might not have the capacity to run complex algorithms. But. Quantum systems are very effective tools. To solve linear mathematical problems. This is why we should develop cryptography that is not dependent on linear methods. Like the Riemann Conjecture. And the Zeta function. In normal cryptography, the Zeta function is used to calculate binary numbers. Then the encryption system counts the ASCII codes with those binary numbers. That has been a very effective way to encrypt data. Quantum computers can calculate as many binary numbers.
The fast, cloud-based neurocomputers can crack those codes. The system is hybrid. And that’s why. It might be in use. The quantum system calculates only the series of binary numbers, and then it shares it with the neurocomputer cloud. That is the networked superfast computers. The system can cut the Riemann series into pieces. And then share those pieces with the computers in the morphing neural network.
The fact is this: we need new types of cryptography to solve the problem that the quantum apocalypse can cause. The old-fashioned cryptography is helpless against quantum and neural computers. This means that we should develop the non-linear encryption methodology. The problem is that we are in the quantum arms race. The new computers make the old-fashioned encryption helpless. And that means. We cannot. Just leave that technology. And play that the past was better. If we make that thing. We offer the key to our systems to China and Russia.
“In 2018, researchers in Paris demonstrated their ability to maneuver neutral atoms by arranging a swarm of atoms in the shape of the Eiffel Tower.” (Qaunta, New Advances Bring the Era of Quantum Computers Closer Than Ever)
The new advances bring quantum computers closer every day than ever. The AI-based systems. Allow for. The control of qubits with new accuracy.
New ideas in quantum technology, such as the ability to use neutral atoms, make a significant advance in quantum computing. This means that the decrease in the number of dead qubits allows the system to transport and compute information with greater precision. The ability to use neutral atoms, which could be stabilized. By using lasers. These are tools for making quantum calculations. More effective. The number of qubits is not the problem. The problem is so-called dead qubits, the qubits that do nothing. In quantum computers. The system stores information in particles. The system stores information in the wave movement at the shell of the particle. And the problem is this: all of those waves cannot involve information. Those waves that do nothing cause the quantum noise. The quantum noise. Means the so-called white noise or free energy in the system.
When a quantum computer starts to transport information between superpositioned and entangled particles, it requires the system to transmit that proposed information by using a higher energy level than the noise. The situation is similar to when we discuss in some large halls. We must get our message. To the person who stands in front of us. The noise around us forces us to talk a little bit louder than others. That causes an effect that other people must raise their voice. And sooner or later, people yell at each other. The quantum computer does the same thing. When it tries to transmit information over the noise. It raises its energy level. The problem is that the system transmits energy also to waves that don’t carry information.
“A new study shows that perovskites can dynamically shift their structure under light in a controllable way. This unusual property hints at future technologies where devices respond directly to light stimuli. Credit: Marina Leite, UC Davis” (ScitechDaily, Scientists Discover “Shape-Shifting” Semiconductors Activated by Light)
This means that when the system tries to get information. Through the system. And raises energy in the quantum system, it also raises the energy level in the noise. So what would be the answer? The system can use tools. That makes it detect and recognize qubits that carry information. The system. It can use atoms that are trapped in the medium. Making a superposition between rare atoms is easier than making a superposition between photons. There is a possibility that the system can use monoatomic objects. Like crystal balls, which are made of purified silicone. The system must create a monotonic quantum field between those objects.
And then. Make the superposition and entanglement between those quantum fields. The thing is that. Quantum computing, quantum cryptography, and quantum networks. They are not the same thing. In quantum computers, information travels between superpositioned and entangled particles. In a quantum network, the system transmits information. In the form of a connection with a physical object. The problem has been how to transmit information into the quantum channel. The answer. It can be the new semiconductors that react to light. The semiconductor can form a pyramid shape. The pyramids take atoms between their heads. Then. The system connects the quantum fields of those atoms. Then it sends a wave through that atom line. The pyramid heads. They can be in the nanotube.
Theoretically, the system could also use artificial viruses. Or put the DNA to travel in the nanotubes. In the first case, the system stores data in the DNA of the virus. And then the system reads that DNA. In the second way, the system. It can send images of those viruses or the DNA code in binary form. This means that the system uses the DNA chemical code and sends those letters to the receiver.
In a quantum network, the system can share messages between multiple physical lines. The system can use TCP/IP and separate each data package. The data package must have information. That tells which message it belongs to, and the position of that data in the data line.
Or, the network. It can use quantum cryptography. In quantum cryptography, the system. It can use certain images. Like a star and a square, to hide information. In binary mode. A star can be one, and a square can be zero.
The system sends the geometrical shapes all the time. And then the system requires another thing. The information on where messages start. Those images. They can be Donald Duck and Mickey Mouse. In that case, Donald Duck can mean one, and Mickey Mouse means zero, in the binary system. The system can also use letter pairs. The “S” can mean one, and “M” can mean zero. The system can hide information by using letters. And this kind. Cryptography can involve multiple layers. The system can notice only the marks. Those are in every other line. In that type of cryptography, every letter can mean a word. The “A” can mean. The “Car”. And this makes. This kind. Of cryptography. A very effective. The systems. Those that change their encryption methods and use multiple internal systems are very hard to break.
https://www.quantamagazine.org/new-advances-bring-the-era-of-quantum-computers-closer-than-ever-20260403/
https://scitechdaily.com/scientists-discover-shape-shifting-semiconductors-activated-by-light/
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