<p>Deep-blue phosphorescent OLEDs (Ph-OLEDs) with high efficiency and stability are essential for advanced display technologies, ensuring sharp image quality and enhanced visibility. In this work, we report a novel class of asymmetric [3 + 2 + 1] coordinated iridium(III) complexes incorporate strongly electron-withdrawing trifluoromethyl (–CF<sub>3</sub>) and fluorine (–F) modified N-heterocyclic carbene ligands. This strategic molecular design enables efficient deep-blue emission. Among these complexes, the CF<sub>3</sub>-substituted Ir(III) complex (<b>CF</b><sub><b>3</b></sub><b>-2</b>) exhibits pronounced charge-transfer (CT) characteristics and a significantly enhanced radiative decay rate (<InlineEquation ID="IEq1"> <EquationSource Format="TEX">\({k}_{r}\)</EquationSource> <EquationSource Format="MATHML"><math> <msub> <mrow> <mi>k</mi> </mrow> <mrow> <mi>r</mi> </mrow> </msub> </math></EquationSource> </InlineEquation> = 1.28 ×10⁶ s<sup>-1</sup>), enabling rapid and efficient phosphorescence at 443 nm. Devices employing <b>CF</b><sub><b>3</b></sub><b>-2</b> demonstrated exceptional maximum external quantum efficiency (<i>EQE</i><sub>max</sub>) of up to 29.0%, with emission centered at 443 nm and Commission Internationale de L’Éclairage (CIE) coordinates of (0.147, 0.089), fulfilling National Television System Committee (NTSC) blue standards for high-quality displays. Meanwhile, devices employing <b>CF</b><sub><b>3</b></sub><b>-1</b> reached an <i>EQE</i><sub>max</sub> of 24.6% with a maximum luminance of 6542 cd m<sup>−2</sup> and CIE<sub>x,y</sub> of (0.152,0.126), demonstrating high color purity and efficiency. A control device fabricated without sensitization using <b>CF</b><sub><b>3</b></sub><b>-1</b> further confirms its intrinsic material stability by exhibiting a remarkable operational lifetime of LT<sub>50</sub> of 3875 h at L = 100 cd m<sup>−2</sup> with CIE<sub>x,y</sub> of (0.132,0.131). Furthermore, hyper-OLEDs were developed using these complexes as phosphorescent sensitizers. The hyper-OLED incorporating <b>CF</b><sub><b>3</b></sub><b>-1</b> with the TADF emitter <i>v</i>-DABNA achieved an impressive device lifetime of LT<sub>50</sub> = 2127 h at 100 cd m<sup>−2</sup>. In parallel, the <b>CF</b><sub><b>3</b></sub><b>-2</b>-sensitized hyper-OLED using DOB2-DABNA-A achieved a deep-blue emission with CIE coordinates of (0.146, 0.067) and a lifetime of LT<sub>50</sub> = 373 h under the same luminance, representing a significant advancement in the practical stability of deep-blue OLEDs. Notably, we demonstrate the successful integration of these deep-blue Ph-OLEDs with OLED-on-TFT microdisplay technology, achieving a pixel resolution of 94 PPI (270 × 270 μm) with programmable emission patterns. This innovative molecular coordination design strategy provides valuable insights into ligand engineering and exciton management, opening new pathways toward high-efficiency, long-lifetime deep-blue OLEDs for next-generation microdisplay and display technologies.</p>

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High-efficiency and stable deep-blue iridium phosphorescent OLEDs with enhanced charge transfer dynamics

  • Siqi Li,
  • Kai-Ning Tong,
  • Meng Zhang,
  • Wei He,
  • Chengcheng Wu,
  • Junki Ochi,
  • Di Wu,
  • Kefei Shi,
  • Xin Wang,
  • Singyeong Jung,
  • Feiyu Kang,
  • Chihaya Adachi,
  • Takuji Hatakeyama,
  • Guodan Wei

摘要

Deep-blue phosphorescent OLEDs (Ph-OLEDs) with high efficiency and stability are essential for advanced display technologies, ensuring sharp image quality and enhanced visibility. In this work, we report a novel class of asymmetric [3 + 2 + 1] coordinated iridium(III) complexes incorporate strongly electron-withdrawing trifluoromethyl (–CF3) and fluorine (–F) modified N-heterocyclic carbene ligands. This strategic molecular design enables efficient deep-blue emission. Among these complexes, the CF3-substituted Ir(III) complex (CF3-2) exhibits pronounced charge-transfer (CT) characteristics and a significantly enhanced radiative decay rate ( \({k}_{r}\) k r  = 1.28 ×10⁶ s-1), enabling rapid and efficient phosphorescence at 443 nm. Devices employing CF3-2 demonstrated exceptional maximum external quantum efficiency (EQEmax) of up to 29.0%, with emission centered at 443 nm and Commission Internationale de L’Éclairage (CIE) coordinates of (0.147, 0.089), fulfilling National Television System Committee (NTSC) blue standards for high-quality displays. Meanwhile, devices employing CF3-1 reached an EQEmax of 24.6% with a maximum luminance of 6542 cd m−2 and CIEx,y of (0.152,0.126), demonstrating high color purity and efficiency. A control device fabricated without sensitization using CF3-1 further confirms its intrinsic material stability by exhibiting a remarkable operational lifetime of LT50 of 3875 h at L = 100 cd m−2 with CIEx,y of (0.132,0.131). Furthermore, hyper-OLEDs were developed using these complexes as phosphorescent sensitizers. The hyper-OLED incorporating CF3-1 with the TADF emitter v-DABNA achieved an impressive device lifetime of LT50 = 2127 h at 100 cd m−2. In parallel, the CF3-2-sensitized hyper-OLED using DOB2-DABNA-A achieved a deep-blue emission with CIE coordinates of (0.146, 0.067) and a lifetime of LT50 = 373 h under the same luminance, representing a significant advancement in the practical stability of deep-blue OLEDs. Notably, we demonstrate the successful integration of these deep-blue Ph-OLEDs with OLED-on-TFT microdisplay technology, achieving a pixel resolution of 94 PPI (270 × 270 μm) with programmable emission patterns. This innovative molecular coordination design strategy provides valuable insights into ligand engineering and exciton management, opening new pathways toward high-efficiency, long-lifetime deep-blue OLEDs for next-generation microdisplay and display technologies.