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Dual role of oxygen-related defects in the luminescence kinetics of AlN:Mn 2 .

Agata LazarowskaMikołaj KamińskiNerine J CherepySebastian MahlikRu-Shi Liu
Published in: Dalton transactions (Cambridge, England : 2003) (2022)
This study presents the impact of temperature and pressure on AlN:Mn 2+ luminescence kinetics. Unusual behavior of Mn 2+ optical properties during UV excitation is observed, where a strong afterglow luminescence of Mn 2+ occurs even at low temperatures. When the temperature increases, the contribution of the afterglow luminescence is further enhanced, causing a significant increase in the luminescence intensity. The observed phenomena may be explained by an energy diagram in which the O N -V Al complex in AlN:Mn 2+ plays a key role. Hence the O N -V Al complex defect in AlN:Mn 2+ plays a double role. When the O N -V Al defect is located close to Mn 2+ ions, it is responsible for transferring excitation energy directly to Mn 2+ ions. However, when the O N -V Al defect complex is located far from Mn 2+ ions, its excited state level acts as an electron trap responsible for afterglow luminescence. Additionally, three models have been tested to explain the structure of the emission spectrum and the strong asymmetry between the excitation and emission spectra. From the most straightforward configuration coordinate diagram through the configuration coordinate diagram model assuming different elastic constants in the excited and ground-states ending by a model based on the Jahn-Teller effect. We proved that only the Jahn-Teller effect in the excited 4 T 1 electronic state with spin-orbit coupling could fully explain the observed phenomena. Finally, high-pressure spectroscopic results complemented by the calculations of Racah parameters and the Tanabe-Sugano diagram are presented.
Keyphrases
  • energy transfer
  • quantum dots
  • room temperature
  • transition metal
  • metal organic framework
  • density functional theory
  • light emitting
  • molecular dynamics
  • molecular dynamics simulations
  • high intensity
  • single molecule