Optical Orientation of Mn2+ Spins in Bulk (Zn, Mn)Se Induced by Magnetic Field

Abstract

The optical orientation of Mn2+ spins in the first excited state 4T1 was experimentally observed in bulk (Zn, Mn)Se (xMn=0.01) in the an external magnetic field of up to 6\,T in Faraday geometry. This occurred during quasi-resonant continuous wave circularly polarized photoexcitation of the intracenter d-d transitions. A non-monotonic dependence of the thermal circular polarization of the intracenter photoluminescence on the magnetic field was observed. A theoretical model is proposed to describe the selection rules for resonant optical d-d transitions of an isolated Mn2+ ion in a ZnSe cubic crystal. These rules are based on the analysis of the total angular momentum symmetry for the ground (6A1) and first excited (4T1) states of the Mn2+ ion. This discussion neglects the specific mechanism for spin-flip processes in a d-shell of the ion during optical excitation. The analysis is founded on the rotational symmetry of the effective total angular momenta and parity for each state as a whole. Additionally, the Jahn-Teller coupling of the excited state orbital parts with tetragonal (e-type) local distortions of the crystal lattice is considered. This coupling results in the segregation of cubic axes and spin projections on these axes due to weak spin-orbit and spin-spin coupling in the excited state. This leads to energy splitting for spin states with their projections of 1/2 and 3/2 on each axis distinguished by specific Jahn-Teller distortion in the corresponding atomic potential minimum. By introducing two different times of relaxation to reach thermodynamic equilibrium for 1/2 and 3/2 states in each Jahn-Teller configuration, an angle dependent optical orientation contribution in photoluminescence polarization arises in the presence of a magnetic field.

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