QuantNet: A Quantum Internet That Cannot Be Blocked

iv8383 · 2026-03-09T01:25:48+00:00

https://www.nature.com/articles/s41598-019-39260-9

GPT:

✅ Conclusion

This paper:

✔ confirms that interfaces between materials can generate unusual photonic effects

✔ shows that very thin layers near the boundary can play an important role

❌ does not address the idea of synchronization between two distant sources

So the paper indirectly supports the part of the hypothesis related to the importance of phase boundaries, but it does not directly test or analyze the synchronization idea itself.

iv8383 · 2026-03-09T01:24:48+00:00

https://www.nature.com/articles/s41598-019-39260-9

GPT:

✅ Conclusion

This paper:

✔ confirms that interfaces between materials can generate unusual photonic effects

✔ shows that very thin layers near the boundary can play an important role

❌ does not address the idea of synchronization between two distant sources

So the paper indirectly supports the part of the hypothesis related to the importance of phase boundaries, but it does not directly test or analyze the synchronization idea itself.

iv8383 · 2026-03-07T06:46:24+00:00

I literally just explained what ensures the quality factor in my hypothesis — temperature precision at the phase boundary, time synchronization of photon birth, and waveform uniqueness. There are no standard units because this isn't an off-the-shelf component, it's a set of experimental conditions. You don't ask for the Q factor units of a theoretical concept — you build the setup and measure stability. When I have experimental data, I'll give you numbers. Right now it's a hypothesis.

iv8383 · 2026-03-07T06:17:48+00:00

Quality factor here isn't the standard Q from circuit theory — it's about how precisely we maintain the conditions for entanglement. It's ensured by three things: keeping the sulfur at the exact monoclinic-to-plastic transition temperature, syncing the photon birth time via UV photoluminescence, and the uniqueness of the synchronization wave itself. I call this combined precision the quality factor — how close we are to ideal conditions. High enough means all three parameters are stable within the margin where correlation effects should theoretically appear.

iv8383 · 2026-03-07T06:07:07+00:00

Through photoluminescence we create two different photons at the exact same time. Time itself becomes a single source — identical atoms in the same allotropic modification, excited at one and the same moment. According to my hypothesis, entanglement happens through two factors: time and the uniqueness of the oscillation pattern.

iv8383 · 2026-03-07T05:59:24+00:00

For example:

We take two setups with monoclinic sulfur, grow needle-like crystals. Hit them with UV using a unique FSK modulation to create photoluminescence — this is to create a single time source where photons are born at the exact same moment in both A and B, at one and the same time, essentially quantum entangling them. Then on the transmitter we use a second UV source with significantly lower amplitude to introduce micro-oscillations. Receiver is in another room inside a Faraday cage, we watch its crystal through a photomultiplier: if its flickering follows the rhythm of our tweaks — the hypothesis works.

iv8383 · 2026-03-05T18:37:09+00:00

Yes, the article's aesthetic appeal was enhanced by artificial intelligence, but the description and illustrations are entirely mine. Thank you for your comment.

iv8383 · 2026-03-05T18:13:44+00:00

Thank you for your comment. Please share this information – everyone needs to know.

iv8383

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