Excited core-level dependence of entanglement between a photoelectron and an emitted X-ray photon in X-ray inner-shell excitation
Abstract
We theoretically investigated how the quantum entanglement between the spin of the photoelectron and the polarization of the emitted X-ray photon depends on the excited core-level, using the 3d→\ 2p and 3d→\ 3p SPR-XEPECS (spin- and polarization-resolved XEPECS) processes for Ti2O3-type system, and the 4f→\ 4d SPR-XEPECS process for CeF3-type system. In the calculation for Ti2O3-type system, we used TiO6 cluster model with the full-multiplet structure of the Ti ion and the charge-transfer effect between Ti 3d and ligand O 2p orbitals. For CeF3-type system, we used ionic model with the full-multiplet structure of the Ce ion. We found two distinct mechanisms for entanglement generation in the 3d→\ 2p and 4f→\ 4d cases. The first is generated by the spin-orbit interaction of the 2p core electron, whereas the second is generated by the spin-orbit interaction of the 4f valence electron and strong exchange interaction between the 4f and 4d electrons. However, in the 3d→\ 3p case with the strong 3d-3p exchange interaction, we found that the entanglement is not generated due to the crystal field effect. These results reveal the existence of two distinct mechanisms for entanglement generation in X-ray inner-shell excitation processes.
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