Spin entanglement, decoherence and Bohm's EPR paradox

E. G. Cavalcanti; P. D. Drummond; H. A. Bachor; M. D. Reid

doi:10.1364/OE.17.018693

Spin entanglement, decoherence and Bohm's EPR paradox

E. G. Cavalcanti, P. D. Drummond, H. A. Bachor, M. D. Reid

Research output: Contribution to journal › Article › peer-review

35 Citations (Scopus)

Abstract

We obtain criteria for entanglement and the EPR paradox for spin-entangled particles and analyse the effects of decoherence caused by absorption and state purity errors. For a two qubit photonic state, entanglement can occur for all transmission efficiencies. In this case, the state preparation purity must be above a threshold value. However, Bohm's spin EPR paradox can be achieved only above a critical level of loss. We calculate a required efficiency of 58%, which appears achievable with current quantum optical technologies. For a macroscopic number of particles prepared in a correlated state, spin entanglement and the EPR paradox can be demonstrated using our criteria for efficiencies η 1/3 and η > 2/3 respectively. This indicates a surprising insensitivity to loss decoherence, in a macroscopic system of ultra-cold atoms or photons.

Original language	English
Pages (from-to)	18693-18702
Number of pages	10
Journal	Optics Express
Volume	17
Issue number	21
DOIs	https://doi.org/10.1364/OE.17.018693
Publication status	Published - 12 Oct 2009

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AU - Drummond, P. D.

AU - Bachor, H. A.

AU - Reid, M. D.

PY - 2009/10/12

Y1 - 2009/10/12

N2 - We obtain criteria for entanglement and the EPR paradox for spin-entangled particles and analyse the effects of decoherence caused by absorption and state purity errors. For a two qubit photonic state, entanglement can occur for all transmission efficiencies. In this case, the state preparation purity must be above a threshold value. However, Bohm's spin EPR paradox can be achieved only above a critical level of loss. We calculate a required efficiency of 58%, which appears achievable with current quantum optical technologies. For a macroscopic number of particles prepared in a correlated state, spin entanglement and the EPR paradox can be demonstrated using our criteria for efficiencies η 1/3 and η > 2/3 respectively. This indicates a surprising insensitivity to loss decoherence, in a macroscopic system of ultra-cold atoms or photons.

AB - We obtain criteria for entanglement and the EPR paradox for spin-entangled particles and analyse the effects of decoherence caused by absorption and state purity errors. For a two qubit photonic state, entanglement can occur for all transmission efficiencies. In this case, the state preparation purity must be above a threshold value. However, Bohm's spin EPR paradox can be achieved only above a critical level of loss. We calculate a required efficiency of 58%, which appears achievable with current quantum optical technologies. For a macroscopic number of particles prepared in a correlated state, spin entanglement and the EPR paradox can be demonstrated using our criteria for efficiencies η 1/3 and η > 2/3 respectively. This indicates a surprising insensitivity to loss decoherence, in a macroscopic system of ultra-cold atoms or photons.

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Spin entanglement, decoherence and Bohm's EPR paradox

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