Quantifying the Spin-Orbital Entanglement in 5d1 Quantum Materials
Abstract
The spin-orbital entanglement in 5d1 transition metal ions embedded in double perovskites, where anomalous effective magnetic dipole moments are frequently observed, is quantified by the spin-orbital von Neumann entropy S vN SO. The framework is grounded on the relativistic crystal field theory, and is illustrated through a series of quantum materials: A2 TaCl6 (A = K, Rb), A2 MgReO6 (A = Ca, Sr, Ba) and Ba2NaOsO6, all analyzed in their paramagnetic phases, alongside the ReF6 molecular system. The entropies are derived from measurements of the optical d-d transitions 7(t2g)←8(t2g) and 8(eg)←8(t2g), and of the effective magnetic dipole moment μ eff. It is demonstrated that, regardless of the system, the Kramers doublet 7(t2g) exhibits no spin-orbital von Neumann entropy. The entropies obtained for the relativistic crystal field states 8(t2g) and 8(eg) uncover that, a larger effective magnetic dipole moment can be attributed to a grater spin-orbital entanglement, yet paradoxically not to a larger spin-orbit coupling constant.
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