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Optimization of the electron transport in quantum dot light-emitting diodes by codoping ZnO with gallium (Ga) and magnesium (Mg).

Hong Hee KimDavid O KumiKiwoong KimDonghee ParkYeonjin YiSo Hye ChoCheolmin ParkO M NtwaeaborwaWon Kook Choi
Published in: RSC advances (2019)
In our study, to optimize the electron-hole balance through controlling the electron transport layer (ETL) in the QD-LEDs, four materials (ZnO, ZnGaO, ZnMgO, and ZnGaMgO NPs) were synthesized and applied to the QD-LEDs as ETLs. By doping ZnO NPs with Ga, the electrons easily inject due to the increased Fermi level of ZnO NPs, and as Mg is further doped, the valence band maximum (VBM) of ZnO NPs deepens and blocks the holes more efficiently. Also, at the interface of QD/ETLs, Mg reduces non-radiative recombination by reducing oxygen vacancy defects on the surface of ZnO NPs. As a result, the maximum luminance ( L max ) and maximum luminance efficiency (LE max ) of QD-LEDs based on ZnGaMgO NPs reached 43 440 cd m -2 and 15.4 cd A -1 . These results increased by 34%, 10% and 27% for the L max and 450%, 88%, and 208% for the LE max when compared with ZnO, ZnGaO, and ZnMgO NPs as ETLs.
Keyphrases
  • quantum dots
  • room temperature
  • light emitting
  • visible light
  • oxide nanoparticles
  • reduced graphene oxide
  • dna damage
  • ionic liquid
  • solar cells
  • oxidative stress
  • electron microscopy
  • perovskite solar cells