Monday, October 20, 2025

The hills and valleys in quantum systems.



"Researchers developed a photonic system that traps cold atoms with chip-scale optics, making quantum technology more compact and accessible. This breakthrough could revolutionize applications from navigation to gravitational sensing. (Artist’s concept.) Credit: SciTechDaily.com". (ScitechDaily, Quantum Revolution: Atoms Trapped on a Chip)

The system that traps ultra-cold atoms can collect very weak information. The system can trap those ultra-cold atoms into the crossing points of the nanotubes. The system can measure. Those atoms’ interactions with their environment. If those ultra-cold atoms are put in the fullerene.  Or a graphene layer, that thing can create a layer that can measure the weakest signals in the universe. The system requires extremely low temperatures. 

The system can see quantum effects only if other effects are suppressed. In quantum sensors, the sensor observes the wobbles and waves on the ultra-cold atom’s quantum fields. There is a possibility that if something like an aircraft is a covered structure. There are ultra-cold atoms that turn the aircraft’s shell into a quantum sensor. 

Those atoms can be between two graphene layers. If those quantum fields can make the quantum cones that aim incoming radiation. Between those graphene layers. That could turn the aircraft into the shadow. 

In some cases, the stealth materials are things like fullerene balls. The fullerene nanotubes are connecting those balls. And there can be an extremely low-energy atom in the middle of those balls. This type of material absorbs the radar echo. And a low-energy atom in the middle of those fullerenes. Pulls energy into it. If there is a so-called nano-diamond in the structure, that nano-diamond can be the nano-pyramid structure. There is a carbon atom in every corner. This structure can have a lower energy atom. In its tip. That aims energy to the structure.



The image above shows that when photons or light waves travel to the quantum layer, they rise above the hill below them. If the energy level in the quantum potential layer is higher than the incoming photon's energy, the photon pulls the field to it. This thing causes an effect. The wave movement travels out from the field. And then stretches it, forming the hill or bubble. 

When a photon or light wave impacts that hill, the hill scatters light. When light beams are scattered. That thing makes the layer hard to detect from the outside. This scattering effect can make it possible to create quantum stealth systems. 

The idea is that. Those energy hills aim radiation into the sides, and that makes the reflection weaker. Sometimes, an idea is introduced about the system that creates the quantum spikes to scatter or aim the incoming radiation through the layer. When the energy pike comes against incoming radiation, that energy pike or energy beam forms the cone. 

That energy spike pushes radiation away from its route. And past the layer. The energy spike can form when the system transmits energy to electrons or protons. These are trapped in the graphene, and then the system can make radiation spikes. By putting those particles into spin. 

If there is an energy pothole near that energy hill, that energy pothole pulls the scattered radiation into it. This thing means that the layer will not be seen from the outside. The outside observer can see the structure only if the observer gets a reflection from it. 


https://scitechdaily.com/quantum-revolution-atoms-trapped-on-a-chip/


https://scitechdaily.com/self-organizing-light-could-transform-computing-and-communications/


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The hills and valleys in quantum systems.

"Researchers developed a photonic system that traps cold atoms with chip-scale optics, making quantum technology more compact and acces...