Spin-orbital entanglement in Cr3+-doped glasses

Abstract

A framework for reconstructing the one-electron spinors, 7 and 8, of Cr3+ ions embedded in glasses from optical measurements has been developed. These spinors provide the basis for calculating the spin-orbital von Neumann entropy, offering a quantitative measure of quantum entanglement within the electronic state. To illustrate the applicability of this concept, an aluminum phosphate glass doped with 1 mol\% chromium was prepared and characterized via optical absorption spectroscopy. By extracting the fundamental electronic parameters, including the spin-orbit coupling constant 3d, the crystal field strength Dq, and the Racah parameters B and C, we demonstrate how the spin-orbital entanglement entropy, S vN SO, can be mapped across different chemical environments. Our analysis reveals that while individual crystal field parameters do not dictate the degree of entanglement, the dimensionless ratio between the spin-orbit coupling and the crystal field strength ( 3d/Dq) exhibits a robust linear correlation with the entropy. This relationship serves as a clear illustration of how the competition between relativistic effects and local symmetry governs the information content of the 3d(Oh) electronic manifold.