Light-hole exciton mixing and dynamics in Mn-doped quantum dots Article Swipe

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Biexciton Exciton Physics Exchange interaction Condensed matter physics Quantum dot Atom (system on chip) Relaxation (psychology) Mixing (physics) Rabi cycle Atomic physics Molecular physics Quantum mechanics Quantum Computer science Social psychology Embedded system Psychology Ferromagnetism

Valeriu Moldoveanu , I. V. Dinu , Radu Dragomir , B. Tanatar ·

YOU? · · 2016 · Open Access · · DOI: https://doi.org/10.1103/physrevb.93.165421 · OA: W2341098242

We investigate theoretically the spectral and dynamical effects of the short-range exchange interaction between a single manganese (Mn) atom hosted by cylindrical CdTe quantum dots and its light-hole excitons or biexcitons. Our approach is based on the Kohn-Luttinger k·p theory and configuration interaction method, the dynamics of the system in the presence of intraband relaxation being derived from the von Neumann-Lindblad equation. The complex structure of the light-hole exciton absorption spectrum reveals the exchange-induced exciton mixing and depends strongly on the Mn position. In particular, if the Mn atom is closer to the edges of the cylinder, the bright and dark light-hole excitons are mixed by the hole-Mn exchange alone. Consequently, their populations exhibit exchange-induced Rabi oscillations which can be viewed as optical signatures of light-hole spin reversal. Similar results are obtained for mixed biexcitons, in this case the exchange-induced Rabi oscillations being damped by the intraband hole relaxation processes. The effect of light-hole heavy-hole mixing is also discussed.