Download
1 / 23
230 likes | 349 Vues
This study by Adán Cabello from the University of Seville, Spain, challenges traditional Bell’s theorem proofs by eliminating the need for distant observers' alignment. The focus is on proving Bell’s theorem without inequalities while addressing issues related to perfect alignment of detectors. The rotationally invariant EPR’s elements of reality play a crucial role in this new approach. The proof demonstrates that perfect correlations occur irrespective of local rotation in setup configurations, thus removing the necessity of shared reference frames. By showcasing the implications of perfect correlations in various measurement scenarios, this study provides a fresh perspective on understanding quantum phenomena and Bell’s theorem concepts.
E N D
Bell’s theorem without inequalities and without alignments Adán Cabello Universidad de Sevilla Spain
Motivation • Usual proofs of Bell’s theorem assume that the distant observers who perform spacelike separated measurements share a common reference frame. • Establishing a perfect alignment between local reference frames requires the transmission of an infinite amount of information. • Yuval Ne’eman argued that the answer to the puzzle posed by Bell’s theorem was to be found in the implicit assumption that the detectors were aligned. • For an experiment to show the violation of a Bell’s inequality, perfect alignment is not essential. However, in the proofs of Bell’s theorem without inequalities (GHZ’s, Hardy’s,...) perfect alignment seems to be essential, since these proofs are based on EPR’s “elements of reality”.
EPR’s elements of reality “If, without in any way disturbing a system, we can predict with certainty (i.e., with probability equal to unity) the value of a physical quantity, then there exists an element of physical reality corresponding to this physical quantity.”
Purpose • To prove Bell’s theorem without inequalities without it being necessary that the observers share a reference frame (i.e., without the need that distant local setups be aligned). • The proof is based on the fact that the required perfect correlations occur for any local rotation of the local setups.
Rotationally invariant EPR’s elements of reality “If, without in any way disturbing a system, we can predict with certainty (i.e., with probability equal to unity) the value of a physical quantity, independently of the orientation of the measurement apparatus used, then there exists an element of physical reality corresponding to this physical quantity.”
Prepare the 8-qubit state Proof where and
The local (4-qubit) observables are Proof where Properties:
Then, if Bob (who is spacelike separated from Alice) measures F, he always obtains 1...
...then he can predict that, if Alice measures F, she always obtains 1
If Alice and Bob measure G, sometimes (in 8% of the cases) they both obtain 1...
In those cases, what if, instead of measuring G, they had measured F?
If EPR’s elements of reality do exist, then, at least in 8% of the cases, both of them would have obtained F=1
