Redox gating and superpositioned photons can make new observation tools possible. And they can boost electronic component development.
"Illustration of redox gating for carrier manipulation and electric field control of the electronic state. The green threads represent functional molecules for redox gating, and the ability to function at low power mimics synaptic switching in the human brain, as represented by the underlying synapse. Credit: Argonne National Laboratory" (ScitechDaily, Unlocking the Future of Microelectronics With Argonne’s Redox Gating Breakthrough)
The new redox gating makes a new step for microelectronic development. And it can be used to create artificial neurons. In the redox gate that Argonne laboratories develop is the plate-looking architecture. That allows it to transport information, at the same time, between two microchips in multiple channels.
And that is the big thing for the table-size solid-state quantum computers. Another thing that this system makes possible is the new type of scanning tunneling microscopes. If the scanning tunneling microscope can use multiple tunneling components at the same time, it can scan large areas. The scanning tunneling microscope hovers particles over the scanning layers. In this kind of system, the trunk is made of layers and graphene nanotubes. The styluses that hover the particle are in those nanotubes.
Another thing is that this kind of system is making new types of observations possible. The most accurate possible microscopic system in the world is the photon, quantum entanglement microscope. In the photonic version, the photon is in superposition and entanglement over the layer like yoyo, and the system can analyze the structures inside the atoms and quarks. The idea of this kind of system is that the photon pair hovers between electrons. And target that the system observes.
The superposition can exist between two different particles. Or it can be a particle's internal ability. In internal superposition. The internal superposition means. That particle's internal quantum fields are superpositioned. That term means the field oscillation in quantum fields positioned so that the fields are identical.
When quantum fields are superpositioned the high-energy wave must be between low-energy fields so that information can travel between those waves. When the system makes superposition and entanglement between wave fields. Information travels between them as it travels between particles from higher energy fields into lower energy fields. The problem with that kind of transmission is that the upper energy field cannot get information if the lower energy field receives information.
The atom-size quantum computers can be in nanotubes between layers. In that kind of system. The laser system can stabilize those Rydberg atoms in nanotubes between layers.
The photonic entanglement microscope can be used to create atom-size quantum computers. Those atomic-size quantum computer bases are in Rydberg atoms, and quantum entanglement can created between electrons in orbiters. Or the system can use some other particles like quarks and gluons. That kind of atomic-size quantum computer can be even more effective than nobody expected.
The atomic-size quantum computers can be in the nanotubes. And the information transport happens through the photonic microscopes that inject information through the holes in graphene nanotube shells. This kind of system can be more effective than any other quantum computer in the world. The network-based quantum computer application can be based on the redox gate that is introduced at the top of this text. The system can host those atom-size qubits in nanotubes. That is between those layers.
https://scitechdaily.com/quantum-entanglement-transforms-next-generation-sensors/
https://scitechdaily.com/unlocking-the-future-of-microelectronics-with-argonnes-redox-gating-breakthrough/
https://en.wikipedia.org/wiki/Redox
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