A silicone offers a new way to make the quantum superposition and entanglement.

"Researchers at the University of Manchester and the University of Melbourne have developed an ultra-pure silicon crucial for creating scalable quantum computers, which could potentially address global challenges such as climate change and healthcare issues." (ScitechDaily, World’s Purest Silicon Paves the Way for Next-Gen Quantum Computers)

A silicone offers a new way to make the quantum superposition and entanglement.

Quantum entanglement does not necessarily happen between two particles. The quantum computer can make that process also between two electromagnetic or quantum fields. The vital thing in that process is that the quantum fields are slight enough. Then the system can make the superposition and entanglement between those quantum fields.

The photoelectric phenomenon makes it possible to transform the solar panels into the quantum computers. But a practical solution requires absolute pure silicone. In those cases, the laser ray transmits data into the silicone layer. The biggest problem with this kind of thing is that the silicone must be pure. And then the system must also stabilize the silicone.

"Scientists have developed a new technique using ultrafast terahertz pulses to control atomic motion in two-dimensional semiconductors, promising advancements in high-speed computing and electronic device development." (ScitechDaily, Scientists Discover New Semiconductor Excitation Technique)

For making silicone-based quantum computers, researchers must purify silicone chemically and physically. "Natural silicon is made up of three atoms of different mass (called isotopes) – silicon 28, 29, and 30. However the Si-29, making up around 5% of silicon, causes a ‘nuclear flip-flopping’ effect causing the qubit to lose information." ScitechDaily, the World’s Purest Silicon Paves the Way for Next-Gen Quantum Computers).

The system must create monoisotopic silicone. That thing can created using centrifugal separation, which is used in the nuclear enrichment process to separate fission-isotopes from non-fissile isotopes. Same way. As a centrifugal separator can separate U-235 from U-238 a similar system can separate the silicon 28, 29, and 30 from each other.

Pure silicone offers the possibility, that computers can manipulate the quantum fields using laser light. The system requires pure silicone because that thing removes the quantum noise from other atoms. And that makes the silicone atoms exchange information in that structure without disturbing signals that can disturb quantum entanglement.

The purest silicon in the world paves the way for the next-generation quantum computers. Silicone is a semiconductor that has a photo-electric phenomenon. This ability can make it possible for the system. That it can use the light to manipulate the qubits. In this kind of qubit system, the electric phenomenon forms the "energy hills" in the structure. And then, the system puts those energy hills in quantum-level superpositioned entanglement.

In some other visions, developers put two 2D silicone layers against each other. Then the system makes quantum superposition and entanglement between those layers. The silicone layers can be separated using graphene. The thing is that there are many ways to make the quantum superposition and entanglement. In some ideas, quantum computers use the atom's quantum fields to make this effect. In that case, the superposition is made between two small-size quantum fields.

https://scitechdaily.com/worlds-purest-silicon-paves-the-way-for-next-gen-quantum-computers/

https://scitechdaily.com/scientists-discover-new-semiconductor-excitation-technique/

https://learningmachines9.wordpress.com/2024/05/14/a-silicone-offers-a-new-way-to-make-the-quantum-superposition-and-entanglement/