Najafi, A.Tarasek, S.Delikanlı, SavaşZhang, P.Norden, T.Shendre, S.Sharma, ManojBhattacharya, A.Taghipour, NimaPientka, J.Dedmir, Hilmi VolkanThomay, T.2021-02-122021-02-122020-032574-0970http://hdl.handle.net/11693/55093We utilized time-resolved photoluminescence (TRPL) spectroscopy to study the excitonic circular polarization (PX) from CdSe/CdMnS core/shell nanoplatelets (NPLs) with a bilayer core. This allows an extensive study of the emission dynamics as a function of magnetic field, temperature, doping concentration, and excitation wavelength. In the presence of an external magnetic field, pulsed excitation below the shell gap results in near-zero excitonic circular polarization PX at all time delays. In contrast, pulsed excitation with photon energy larger than the shell gap results in a rapid (100 ps) buildup of the excitonic circular polarization which subsequently remains constant at a level of up to 40%. We propose a model to describe the dynamics which takes into account the exchange interaction between carrier and magnetic ion (Mn) spins. The studied system exhibits a fast switchable excitonic circular polarization, implying possible applications in lasers and light emitting diodes.EnglishNanoplateletsQuasi-2DTime-resolved photoluminescenceSpd exchange interactionMagneto-optical switchCdSe/CdMnS nanoplatelets with bilayer core and magnetically doped shell exhibit switchable excitonic circular polarization: Implications for lasers and light-emitting diodesArticle10.1021/acsanm.0c00365