Determining the Spin Density Matrix via Its Rank and Probing the Quantum Entanglement and Bell Non-Locality at the Lepton Colliders

Abstract

Considering two-fermion Fa Fb productions and decays via one scalar or photon exchange at the e+e- collider, we show that the rank rρ of spin density matrix ρ is equal to the number of degrees of freedom of the mediator. For one generic scalar exchange, the spin density matrix is rank one for a pure state. With rank-one condition, we can determine the spin analyzing powers for Fa and Fb and their product if the CP symmetry is violated and conserved, respectively, and probe the CP violation. These results can be applied to the ηc Λ Λ at the BESIII experiment and the Higgs ττ at the LHC. For one photon exchange, the spin density matrix is rank two for a mixed state. Considering the Λ Λ productions and decays at the BESIII experiment as an example, we show that the spin analyzing powers for Fa and Fb can be determined by the rank-two conditions in details. Therefore, we can reconstruct the spin density matrices, probe the quantum entanglement and Bell non-locality, and evade the no-go theorem. Furthermore, we conjecture that the N× N spin density matrix with rρ N-2 can be reconstructed at the lepton colliders in general.