The original formula of Bell inequality(BI) in terms of two-spin singlet has to be modified for the entangled-state with parallel spin polarization. Based on classical statistics of the particle-number correlation, ...The original formula of Bell inequality(BI) in terms of two-spin singlet has to be modified for the entangled-state with parallel spin polarization. Based on classical statistics of the particle-number correlation, we prove in this paper an extended BI, which is valid for two-spin entangled states with both parallel and antiparallel polarizations. The BI and its violation can be formulated in a unified formalism based on the spin coherent-state quantum probability statistics with the statedensity operator, which is separated to the local and non-local parts. The local part gives rise to the BI, while the violation is a direct result of the non-local quantum interference between two components of entangled state. The Bell measuring outcome correlation denoted by PB is always less than or at most equal to one for the local realistic model(PB^lc≤ 1)regardless of the specific superposition coefficients of entangled state. Including the non-local quantum interference the maximum violation of BI is found as PB^max =2, which, however depends on state parameters and three measuring directions as well. Our result is suitable for entangled photon pairs.展开更多
基金Project supported in part by the National Natural Science Foundation of China(Grant Nos.11275118 and U1330201)
文摘The original formula of Bell inequality(BI) in terms of two-spin singlet has to be modified for the entangled-state with parallel spin polarization. Based on classical statistics of the particle-number correlation, we prove in this paper an extended BI, which is valid for two-spin entangled states with both parallel and antiparallel polarizations. The BI and its violation can be formulated in a unified formalism based on the spin coherent-state quantum probability statistics with the statedensity operator, which is separated to the local and non-local parts. The local part gives rise to the BI, while the violation is a direct result of the non-local quantum interference between two components of entangled state. The Bell measuring outcome correlation denoted by PB is always less than or at most equal to one for the local realistic model(PB^lc≤ 1)regardless of the specific superposition coefficients of entangled state. Including the non-local quantum interference the maximum violation of BI is found as PB^max =2, which, however depends on state parameters and three measuring directions as well. Our result is suitable for entangled photon pairs.
