Influence of detector motion in Bell inequalities with entangled   fermions

Andre G. S. Landulfo; George E. A. Matsas

arXiv:0902.2449·quant-ph·May 13, 2015

Influence of detector motion in Bell inequalities with entangled fermions

Andre G. S. Landulfo, George E. A. Matsas

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TL;DR

This paper explores how relativistic motion of detectors affects quantum entanglement tests, showing that high-speed detector movement can prevent violation of Bell inequalities with entangled fermions.

Contribution

It demonstrates that relativistic motion can suppress Bell inequality violations in entangled fermions, highlighting the importance of detector motion in quantum nonlocality tests.

Findings

01

Bell inequality violation disappears at high detector velocities

02

Relativity influences quantum entanglement measurements

03

Quantum mechanics predicts no violation with fast-moving detectors

Abstract

We investigate how relativity influences the spin correlation of entangled fermions measured by moving detectors. In particular, we show that the Clauser-Horne-Shimony-Holt Bell inequality is not violated by quantum mechanics when the left and right spin detectors move fast enough.

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