<p>In this study, we propose a micro neutron star-like gravity model to explain the phenomenon of superluminal response in quantum entanglement experiments. In our model, measurements of the spin state of one electron may cause that electron to emit ultralong-wavelength photons to inform another entangled electron. Therefore, one electron will be connected to another electron through the Coulomb interaction of ultra-low energy photons. The scattering of ultra-long wavelength light can be ignored, and only the super-strong gravity around the atomic nucleus is considered. In this model, the ultra-long wavelength light close to the atomic nucleus is mainly affected by the super-strong gravitational field of each atomic nucleus, and the time passing through each atomic nucleus will be shortened by Δ<i>t</i> on average, and a superluminal response is finally observed. Our model does not violate special relativity but discusses the measurements between different reference coordinates within the framework of general relativity.</p>

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The explanation of the superluminal response between two quantum-entangled electrons based on the micro super-strong gravitational sources

  • Ting-Han Pei

摘要

In this study, we propose a micro neutron star-like gravity model to explain the phenomenon of superluminal response in quantum entanglement experiments. In our model, measurements of the spin state of one electron may cause that electron to emit ultralong-wavelength photons to inform another entangled electron. Therefore, one electron will be connected to another electron through the Coulomb interaction of ultra-low energy photons. The scattering of ultra-long wavelength light can be ignored, and only the super-strong gravity around the atomic nucleus is considered. In this model, the ultra-long wavelength light close to the atomic nucleus is mainly affected by the super-strong gravitational field of each atomic nucleus, and the time passing through each atomic nucleus will be shortened by Δt on average, and a superluminal response is finally observed. Our model does not violate special relativity but discusses the measurements between different reference coordinates within the framework of general relativity.