Shape-shifting membranes that change their shape and profiles are tools that can change things like pollution removal. The same things can also make it possible to create intelligent medicines. Self-assembly structures can be used to analyze neural structures. The self-shaping structures can also operate as extremely sharp loudspeakers and be used in stealth technology.
Those fundamental materials require new ways to create computers. Things like memory plastics and knowledge of the memory in human brains are things, that make it possible to create intelligent materials that react with their environment. Researchers found that memory is not limited to the neurons. Tissues around them participate in the memory process.
That means there are structures in those tissues that can store information, and those structures can be transferred into the plastics and nanomachines. The intelligent proteins that control the self-assembly process of the nanomachine and nanostructures are tools that can make them more powerful.
Advanced nanotechnology requires new types of microchips and memory solutions. The DNA and mRNA molecules are excellent tools for data storage and data transmitters. But how to transfer that information into molecules that should interact with outside effects?
"New phase-transformable porous materials with metal-organic polyhedra that can change their phase among crystal, glass, and liquid. Credit: KaiLi Chien" (ScitechDaily, Shape-Shifting Membrane Transforms Carbon Capture Technology)
The intelligent proteins can recognize things like target cells. When they see them. The protein can open its structures. And release the medicine into those cells. The protein can simply fill the targeted cell. Or it can send the DNA or RNA bite to the cell. And those genomes can simply order those cells to die.
The nanomachines are sensitive to magnetic fields and non-controlled thermal energy. When ions and anions move in the reaction chamber the outside magnetic fields and IR radiation can cause catastrophic situations. Things like enzyme reactions require extremely well-controlled environments and things like thermal conditions must be fully controlled.
That means traditional microelectronic systems can disturb those molecules. The problem is similar to quantum computers. The traditional microchips cannot control the system as they should. They form sometimes too much heat and too high high-level EM-fields that can cause non-wanted oscillations in the reactions. Those oscillations destroy the structures.
For controlling the system controller must have complete knowledge of it. When nanotechnical systems make the nanomachines. They must have systems that observe the movement and reactions in the chamber.
AI and neural networks make it possible for the system can control multiple points in reaction at the same time. The system can use miniature lasers, ion cannons, and phononic acoustic systems to push and pull atoms and molecules in the reaction chamber. Things like ultra-sharp scanners that can observe electrons at their orbitals are things, that allow the system to observe the nanomachines.
https://scitechdaily.com/astrocytes-the-brains-hidden-memory-architects-revealed/
https://scitechdaily.com/could-data-be-stored-in-plastic-heres-how-it-works/
https://scitechdaily.com/mind-blowing-discovery-scientists-discover-that-memories-are-not-only-in-the-brain/
https://scitechdaily.com/neural-nanotechnology-nanowire-networks-learn-and-remember-like-a-human-brain/
https://scitechdaily.com/shape-shifting-membrane-transforms-carbon-capture-technology/
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