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A new quantum phenomenon in ordinary light.


"Quantum dynamics emerge from classical light! Researchers unveil hidden coherence, unlocking breakthroughs for scalable quantum tech and advanced imaging systems. Credit: SciTechDaily.com" (ScitechDaily, Scientists Found a Quantum Surprise in Ordinary Light)

"Through advanced techniques, they isolated subsystems exhibiting quantum interference, paving the way for scalable quantum technologies and new insights into many-body systems."(ScitechDaily, Scientists Found a Quantum Surprise in Ordinary Light)

The quantum phenomenon in the photonic whirl can also make things like protective fields possible. Those entangled photons will not let material or energy travel through them. 

The new quantum phenomenon challenges ordinary physics. That thing can tell something about black holes and other complicated systems. There is a possibility that photons can entangle in the photonic whirls.  It's possible photons can close some space inside those photon whirs.  And that can cause a situation in which information or some part of information cannot come through that photonic whirl.

"Using advanced techniques such as photon-number-resolving detection and orbital angular momentum (OAM) measurements, the team transformed a classical pseudothermal light field into isolated multiphoton subsystems. Within these subsystems, they observed two contrasting behaviors:" (ScitechDaily, Scientists Found a Quantum Surprise in Ordinary Light)

 



"This diagram illustrates the process of multiparticle scattering mediated by twisted paths endowed with orbital angular momentum (OAM). The number of photons in each twisted path is measured and correlated using photon-number-resolving (PNR) detectors. Credit: Mingyuan Hong" (ScitechDaily, Scientists Found a Quantum Surprise in Ordinary Light)

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1) Classical Coherence: The majority of subsystems behaved predictably, consistent with the principles of classical optics.


2) Quantum Coherence: A smaller subset exhibited interference patterns reminiscent of quantum phenomena observed in entangled photon systems.


(ScitechDaily, Scientists Found a Quantum Surprise in Ordinary Light)


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The quantum phenomenon in the photonic groups makes it possible to share information between multiple systems. That makes those quantum systems scalable. 

Making the new quantum solutions possible. If the photon looks like the donut. That we can see in image 3. That thing means that the entropy is also in the photon. The entropy is the thing that destroys all systems. When the size of the system in comparison to its material grows that thing leaves space in the system. And that increases entropy. 


The scalable quantum technology makes it possible to form quantum computer networks and quantum sensors. 


It improves quantum technology. It's possible that many (or all) other physical systems hide the quantum phenomenon. Classical physics handles the entireties. In quantum versions of the physical models, the quantum phenomenon can involve sub-phenomena. 

Quantum physics handles parts of entireties.  Things like quantum whirls can exist on the surface of quarks. Those quantum phenomena and sub-quantum phenomenons can explain entropy in all systems. The quantum whirl can form entropy even in the smallest systems. And those whirls cause the rise of entropy. 




Image 3. Can a photon look like this donut? Or can some superstring tie around it? Like in image 4. (Images by Gemini) 



Image 4.


One of the things that can cause problems in the event handling in quantum systems is time dilation. There is no time in photons. That means photon moves all the time. 

When we look at the image of the photon we see the donut-shaped structure. The interesting thing is the photon doesn't turn older in the frame. That can mean that the photon is moving all the time. The photon can move like a wheel around its axle. 

Or it can roll itself crossing the structure. 

Maybe the photon has some kind of substructure. If that movement crosses the shape of photons is like a wheel that forms crossing wheels. Maybe the photon looks like the thing that we see in image 3. That means that every sub-particle can rotate independently. 

And it can drive wave movement through it. So if the string of wave movement travels through that structure it can glue two photons together. When we look at things like quantum entanglements and energy bridges that transport data in that thing. 

There should be entropy in the structure that transports data in the superposition and entanglement. In all structures is the entropy that destroys the quantum system. 

That means quantum whirls can destroy the smallest possible systems. Those whirls can form in the superstrings and they are the beginning of entropy that rises all the time. 


https://scitechdaily.com/scientists-found-a-quantum-surprise-in-ordinary-light/




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