The shocking fact is that our brain uses quantum computation.

The thing, that makes our brains so effective is that they use quantum computing. So in our brain, chemical qubits are traveling between neurons. And that thing with the ability to begin the operation makes our brain so effective that the best quantum computers are losers. Our brain is an extreme tool that uses at least two speeds in computing.

Fast-speed computing is basing the electric phenomena that travel on the axons' cores. And another version of computing in the human brain is the slower model that uses chemical or electrochemical qubits called neurotransmitters.

The brain uses the electric mode to send signals to neurons on how they should handle the qubit or neurotransmitters. That is coming after the electric signal. The purpose of faster computing is that brain can use it in fast reactions. And the slower mode is used to analyze the data.

The brain uses electric computing to ask what neuron has certain information. And when that information is found, the neuron creates the neurotransmitter. Also, there is the possibility that electric computing is meant to tell neurons what kind of neurotransmitters they must create. And that allows the system to start the data-handling process. At the same moment in multiple points of the brain.

By researching the brain neurologists and computer experts can create faster and more powerful computers that can learn things similarly to the human brain. Those neural quantum computers can drive the most complicated algorithms. But they are more flexible and suitable for autonomous robots than regular quantum computers.

When researchers know how the brain operates, they can model that thing to quantum computers.

The human brain could be a model for quantum computers that can revolutionize robotics. If we want to make a human-looking humanoid robot that can operate on Jupiter, Saturn, and other gas giants' moons' surfaces we must make a system that is more autonomous than any other robot before. The system can use a hybrid system where the electric signals are controlling quantum routers, switches, and gates.

These kinds of the system require lightweight powerful quantum computers. In those lightweight but powerful systems, the electric impulse tells how the system should route the qubit. So, at the first, the electric impulse to quantum routers and gates, and then those gates can drive qubits anywhere where the system wants.

https://scitechdaily.com/shocking-experiment-indicates-our-brains-use-quantum-computation/

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