Quantum Physics


Entangled States and Quantum Causality Threshold in the General Theory of Relativity

Authors: Dmitri Rabounski, Larissa Borissova, Florentin Smarandache

This article shows, Synge-Weber's classical problem statement about two particles interacting by a signal can be reduced to the case where the same particle is located in two different points A and B of the basic space-time in the same moment of time, so the states A and B are entangled. This particle, being actual two particles in the entangled states A and B, can interact with itself radiating a photon (signal) in the point A and absorbing it in the point B. That is our goal, to introduce entangled states into General Relativity. Under specific physical conditions the entangled particles in General Relativity can reach a state where neither particle A nor particle B can be the cause of future events. We call this specific state Quantum Causality Threshold.

Comments: 7 pages

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Submission history

[v1] 6 Mar 2010

Unique-IP document downloads: 110 times

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