What makes chaos interesting in next-generation quantum computing?

Chaos can protect order. 

Nanotechnology requires a new type of computer. And the answer for nanomachine control could be atom-size quantum computer systems. 

Superposition between quarks in baryons can use in quantum computers. That is smaller than an atom. Those systems can use in intelligent nano-machines. And they can revolutionize almost everything. Theoretically, there is the possibility that this kind of quantum computer can hybridize with living neurons. 

The quantum-size quantum computers can also transport information to the nervous system. The nano-quantum computer can fly to the axons and transport information to neurons. And that makes this kind of system an interesting tool. This kind of system can also make it possible to restore destroyed neurons. The information that can be saved will transport to the cloned neurons by using a nano-size quantum computer. 

Those small-size quantum computers don't need very much power. So it can take electricity for the ultra-small microchips from the nervous system. And that kind of bio-hybrid quantum computer can be the most powerful system in the world. The nano-size quantum computers also can use living cells to make electricity for those systems. 

Nano-size quantum computers can be the qubits themselves. In this model, the computing system sends the quantum computer to the receiver. And that thing makes it possible to transport information over extremely long distances. And maybe that kind of system is used in nano-size probes that travel in the solar system and beyond. 

The nano-size probes could form a cloud that researches multiple objects. They can enter many places where regular probes cannot go. And in some visions, the nano-probes can even research alien bodies if we someday find other species in some other solar system. In that model, those systems slip into the target body and make their missions. 

"A spinning neutron disintegrates into a proton, electron, and antineutrino when a down quark in the neutron emits a W boson and converts into an up quark. The exchange of quanta of light (γ) among charged particles changes the strength of this transition. Credit: Image courtesy of Vincenzo Cirigliano, Institute for Nuclear Theory" (ScitechDaily.com/Reimagining the Universe: Right-Handed Currents and Neutron Decay Interaction)

Chaos can protect order. 

Mathematical algorithms that find stability in chaos are the next-generation tools for quantum technology. The idea is that the information. That the system sends can hide in chaos, which makes it hard to detect the information carriers. The idea is like hiding the hard disk in the sand pile. And in a quantum system, the information carrier would be some kind of electron that travels in the whirling electromagnetic field. 

The skyrmion that is made around the electron (or photon etc.) qubit can protect information when it travels between transmitter and receiver. That thing makes it hard to detect the information transporter. The electromagnetic field can also protect the qubit when it travels in a quantum channel. 

One way to protect information against outside attackers is to store it in short-term particles. When the system downloads information from short-term particles those particles can divide or be destroyed after use. And that increases the data security. 

Hiding the information transporter is one way to keep the quantum system safe. The quantum system can drive information in short-term particles or neutrons. Neutrons or quarks, internal particles of neutrons can act as quantum computers. In that model, the system drives information to the neutron. Then the quantum system in the neutron will work with the solution. And when a certain time is gone, the system divides neutrons and drives information back to the binary system.

This thing is called the "closed box" model. The closed box is one variation of the famous Scrödinger's cat. The idea of this type of computing is simple. The data handler is like the person who sits in the box. Then the outside actor gives a mission to that actor, and after a certain time, the actor must show the answer or result. The idea is that outside actors cannot affect the data handler who sits in the box. The idea is that the outside actor needs only an answer. 

And how the outside actor confirms that there are no mistakes. That actor can give work to multiple boxes at the same time. And if the answers are identical. That tells that there is a big possibility. That there are no errors in the answer. And the outside actor can give the same mission to the system twice. That thing denies the possibility that some common non-predicted effect affects at the same time to all data handlers. 

Removing outside effects is a vital thing in computing. If the system works wrong, there is no difference in what causes the error. The error means that the system cannot make its duty. 

This is why things like Majorana particles are interesting in quantum computing. When the operator sends the second pulse of the missions to the system those data-handlers should be identical. The cloned actors make it possible that the system can make similar operations in precisely similar ways. The idea is that. When the missions come the qubits are doubling the data. In that process, some qubits are storing data that they get. When the first pulse travels through the system it waits for a moment. And then it sends the second pulse of identical data. 

The idea is that this application removes the possibility that things like FRBs are interacting with the entire system where all data handling lines acting, in the same way, are wrong. In that model quantum computer's lines give identical answers but those answers could be wrong. Before the second data pulse is sent the qubits would also send information back to the sender to make sure that there are no changes in information while it's stored. 

https://www.quantamagazine.org/flow-proof-helps-mathematicians-find-stability-in-chaos-20230615/

https://scitechdaily.com/reimagining-the-universe-right-handed-currents-and-neutron-decay-interaction/