The molecules offer new ways to create data security.

"Image depicting the control of polariton particles using electric-field tip-enhanced strong coupling spectroscopy. Credit: POSTECH" (ScitechDaily, Light-Matter Particle Breakthrough Could Change Displays Forever). The system can use the same method to create qubits.

Light-particle interaction that can change displays forever can also make it possible to unlock a new way to create qubits. The system can make it possible to trap things like electrons between two layers. And then. The system can create the quantum entanglement between those electrons or maybe even atoms.

The superposition between atoms is possible if the system can make a very accurate superposition between those atom's quantum fields. Or the system must just descramble information that it transports between atoms.

In this image, you can see the energy hills and the system can make quantum entanglement between those hills.

Holographic displays. That creates hovering holograms over them those holograms can used as optical communication tools. The system traps the qubit in those holograms. And then it transports information into them. The blinking holograms also offer the possibility to make an optical data network.

"Scientists have discovered that molecules scramble quantum information at rates comparable to black holes, affecting chemical reactions and offering insights for controlling quantum computing systems. Credit: SciTechDaily.com" (ScitechDaily, Quantum Scrambling: Chemical Reactions Rivaling Black Holes)

Molecules offer impressive paths for data security.

Researchers saw that molecules can scramble information as effectively as black holes. And that can make a big advance in quantum technology. If we think about the possibility of scrambling and descrambling information. We can say that a molecule twists information in a certain way. In that system, the information is like tangled woolen yarn. When the woolen yarn is tangled. It creates a structure that seems impossible to take in use.

But if we have patience. We can turn those yarns into straight form. Same way molecules can entangle information. And then. The receiving system must just make the same actions that the encoding molecule made backward.

We must understand that certain movements create this tangled structure. And to disentangle that mess, we should only make those movements backward.

"Researchers have used neutron spectroscopy to uncover the unique, moonlander-like movement of triphenylphosphine on graphite, advancing our understanding of molecular motion and its applications in material science.Credit: TU Graz" (ScitechDaily, A Molecular Moonlander: PPh3’s Movement Challenges Conventional Science)

Moon lander molecules can used to create big advances in data security and nanotechnology.

The molecular moon-lander that acts as a molecular-size USB can improve data security. This molecule can hover over a graphite layer. And it can offer very interesting opportunities for data security and nanotechnology.

The triphenylphosphine (PPh3) molecule offers a new way to secure data communication. The film shows how the molecule interacts with the layer. And when one part of it comes closer to the contact point, it can release data. That system is stored in it. This kind of thing can make chemical qubit possible.

If there is a ring of metal atoms around the carbon ring. That system can store information in those atoms. Then the system can use that structure to turn the data row into data lines.

That molecule can act like a miniature USB stick. And it can transport data between two layers. At least. If there are some metal atoms where the system can store information. The molecular moon lander can also operate as a tool for nanotechnology. And it can transport things like enzymes to precise points. The molecular moon lander as this molecule is called can also act as a miniature antenna. That scans the objects that are on the graphite or graphene layers.

https://scitechdaily.com/a-molecular-moonlander-pph3s-movement-challenges-conventional-science/

https://scitechdaily.com/light-matter-particle-breakthrough-could-change-displays-forever/

https://scitechdaily.com/quantum-scrambling-chemical-reactions-rivaling-black-holes/

The LK-99 could be a fundamental advance even if it cannot reach superconductivity in 400K.

The next step in superconducting research is that LK-99 was not superconducting at room temperature. Or was it? The thing is that there is needed more research about that material. And even if it couldn't reach superconductivity in 400K that doesn't mean that material is not fundamental. And if LK-99 can maintain its superconductivity in 400K that means a fundamental breakthrough in superconducting technology. The LK-99 can be hype or it can be the real thing. The thing is, anyway, that high-voltage cables and our electric networks are not turning superconducting before next summer. But if we can change the electric network to superconducting by using some reasonable material. That thing can be the next step in the environment. Superconductors decrease the need to produce electricity. But today cooling systems that need lots of energy are the thing that turn superconductors that need low temperatures non-practical for everyday use. When the project begins there is lots of ent

Black holes, the speed of light, and gravitational background are things that are connecting the universe.

Black holes, the speed of light, and gravitational background are things that are connecting the universe. Black holes and gravitational waves: is black hole's singularity at so high energy level that energy travels in one direction in the form of a gravitational wave. We normally say that black holes do not send radiation. And we are wrong. Black holes send gravitational waves. Gravitational waves are wave movement or radiation. And that means the black holes are bright gravitational objects. If we can use water to illustrate the gravitational interaction we can say that gravitational waves push the surface tension out from the gravitational center. Then the other quantum fields push particles or objects into a black hole. The gravitational waves push energy out from the objects. And then the energy or quantum fields behind that object push them into the gravitational center. The elementary particles are quantum fields or whisk-looking structures. If the gravitational wave is

The CEO of Open AI, Sam Altman said that AI development requires a similar organization as IAEA.

We know that there are many risks in AI development. And there must be something that puts people realize that these kinds of things are not jokes. The problem is how to take control of the AI development. If we think about international contracts regarding AI development. We must realize that there is a possibility that the contract that should limit AI development turns into another version of the Nuclear Non-Proliferation Treaty. That treaty didn't ever deny the escalation of nuclear weapons. And there is a big possibility that the AI-limitation contracts follow the route of the Nuclear Non-Proliferation Treaty. The biggest problem with AI development is the new platforms that can run every complicated and effective code. That means the quantum computer-based neural networks can turn themselves more intelligent than humans. The AI has the ultimate ability to learn new things. And if it runs on the quantum-hybrid system that switches its state between binary and quantum states,

Cogito ergo sum. I think; therefore I am (René Descartes, French philosopher)

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