Nature of red luminescence band in research-grade ZnO single crystals: A “self-activated” configurational transition

Abstract: By implanting Zn þ ions into research-grade intentionally undoped ZnO single crystal for facilitating Zn interstitials (Zn i ) and O vacancies (V O ) which is revealed by precise X-Ray diffraction rocking curves, we observe an apparent broad red luminescence band with a nearly perfect Gaussian lineshape. This red luminescence band has the zero phonon line at $2.4 eV and shows distinctive lattice temperature dependence which is well interpreted with the configurational coordinate model. It also shows a low "kic… Show more

“…Previous investigations on red luminescence (1.8-2.0 eV) in ZnO emphasized the role of V Zn clusters [35], I Zn [36], V O [37], combined effect of both V Zn and I Zn [5] and in general shallow donor electron transition to deep acceptor states [38]. In our view, low temperature red luminescence in ZnO, at least here in 500I and 800I samples, originates from V Zn -2V O type defects.…”

“…The qualitative understanding mentioned above has evolved several decades before, however, assignment of particular ZnO PL peak to specific defect site is still a matter of debate [4][5][6][7].…”

Low temperature photoluminescence from disordered granular ZnO

“…Previous investigations on red luminescence (1.8-2.0 eV) in ZnO emphasized the role of V Zn clusters [35], I Zn [36], V O [37], combined effect of both V Zn and I Zn [5] and in general shallow donor electron transition to deep acceptor states [38]. In our view, low temperature red luminescence in ZnO, at least here in 500I and 800I samples, originates from V Zn -2V O type defects.…”

“…The qualitative understanding mentioned above has evolved several decades before, however, assignment of particular ZnO PL peak to specific defect site is still a matter of debate [4][5][6][7].…”

Low temperature photoluminescence from disordered granular ZnO

“…Similarly, for yellow and orange-red emissions, there are many competing hypotheses, but the community has mainly attributed oxygen interstitials [34,38,39] as the primary candidate. More recently, red emission has been attributed to negatively charged zinc and positively charged oxygen vacancies within ZnO nanocrystals [40] and zinc interstitial-oxygen vacancy complexes or zinc-oxygen divacancies in ZnO single crystals [41]. Often, the contradictory results for ZnO defect emission may be attributed to the plethora of growth conditions that inevitably control what defects are introduced into the crystallographic structure of ZnO [4].…”

Room-temperature single-photon emission from zinc oxide nanoparticle defects and their in vitro photostable intrinsic fluorescence

“…In other words, matrix Gd 3+ ions behave as extrinsic activators that act as energy donors. In different host lattices the nature of the self-activation centers has been related to the point distortions of lattice caused by deviations from stoichiometry [9,10]. In our case, the most possible intrinsic defects involved in absorption and luminescence processes are either interstitial Gd 3+ ions or Gd 3+ at normal lattice sites associated with other nearest point defects.…”

Luminescence of rare-earth ions and intrinsic defects in Gd₂O₃matrix