Deep-Blue Phosphorescence from Perfluoro Carbonyl-Substituted Iridium Complexes

Lee, Sunghun; Kim, Seul-Ong; Shin, Hyun Mu; Yun, Hui‐Jun; Yang, Kiyull; Kwon, Soon‐Ki; Kim, Jang‐Joo; Kim, Yun‐Hi

doi:10.1021/ja4065188

Cited by 248 publications

(143 citation statements)

References 44 publications

(23 reference statements)

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“…E ox refers to oxidation potential of molecules relative to the reference electrode used in measurement [35,36]. LUMO values can be deduced using HOMO and the [27,37,38] obtained from the absorption spectra shown in Figure 1(a). All the photophysics and electrochemical data are summarized in Table 1.…”

Section: Photophysics and Electrochemical Propertiesmentioning

confidence: 99%

Influences of fluorination on homoleptic iridium complexes with C∧N=N type ligand to material properties, ligand orientation and OLED performances

et al. 2014

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Two new iridium complexes with C^N=N type ligand (i.e., Ir(BFPPya) 3 {tris[3,6-bis(4-fluorophenyl)pyridazine]iridium(III)} and Ir(BDFPPya) 3 {tris[3,6-bis (2,4-di-fluorophenyl)pyridazine]iridium(III)}) attaching with fluorine atoms, were synthesized and the effects of fluorination on the material properties and device performance were investigated. Compared with our previously reported fluorine-free analogue material, that is Ir(BPPya) 3 {tris[3,6-bis(phenyl)pyridazine]iridium(III)}, blue shifts in the emission spectra as well as in the long wavelength region of the absorptions were observed. The photoluminescence quantum yield (PLQY) (0.44 and 0.84 vs 0.29), phosphoresces lifetime (0.88 and 1.31 vs 0.66 s), and oxidation potential (1.10 and 1.37 vs 0.95 V) increased obviously after fluorinating the ligand. In contrast, the thermal stability of the iridium complexes decreased slightly (Td: 435 and 402 vs 440 °C). In the density functional theory (DFT) calculations, by comparing the steric shape of the three ligands within one optimized molecule, orientational differences among the complexes were observed. In OLED device studies, bluish green electroluminescence with peak emission of 500 nm, using the electron-transporting host of TPBI [2,2',2''-(1,3,5-benzenetriyl)tris(1-phenyl-1H-benzimidazole)] and the most fluorinated dopant of Ir(BDFPPya) 3 , was achieved with maximum efficiency of 20.3 cd/A. On one hand this efficiency is not satisfactory considering a high PLQY of 0.84. On the other hand with the similar device structure, that the (HOMO-LUMO)s of all the dopants are wrapped within that of the host TPBI, and all the triplet energies of the dopants are smaller than that of the host TPBI, it is abnormal that the ordering of device efficiencies is contradictory to that of PLQY. Assisting with the phosphorescent spectrum of TPBI and the absorption spectra of the dopant, the contradiction was interpreted reasonably.

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Section: Photophysics and Electrochemical Propertiesmentioning

confidence: 99%

Influences of fluorination on homoleptic iridium complexes with C∧N=N type ligand to material properties, ligand orientation and OLED performances

et al. 2014

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“…1b. The HOMO energy level was calculated from the oxidation potential (E ox ), while the LUMO energy level was derived by combining the HOMO level with the optical bandgap obtained from the absorption edge [24,25]. To determine the oxidation potentials, the reference electrode was calibrated using a ferrocene/ferrocenium salt couple, which is assumed to have a redox potential with an absolute energy level of À4.80 eV in vacuum.…”

Section: Resultsmentioning

confidence: 99%

Non-interlayer and color stable WOLEDs with mixed host and incorporating a new orange phosphorescent iridium complex

Guo

Zhang

Zhuo

et al. 2014

Organic Electronics

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“…Nonetheless, the device that used emitter 71 had a CIE of (0.19, 0.44), which is more greenish blue compared to the (0.16, 0.36) CIE of the device that used emitter 70. Lee et al 69 developed emitters 72 and 73 as perfluoro carbonyl-substituted iridium complexes for the development of phosphorescent blue dopants with high efficiency and emission of deep-blue light (see Fig. 11).…”

Section: Blue Phosphorescent Dopantsmentioning

confidence: 99%

Recent progress in the use of fluorescent and phosphorescent organic compounds for organic light-emitting diode lighting

et al. 2015

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Abstract. Organic light-emitting diodes (OLEDs) have attracted considerable attention in both academic and industrial circles. Certain properties of OLEDs make them especially attractive in the lighting market, including area emission characteristics not found in other existing light sources, environmentally friendly efficient use of energy, large area, ultra-light weight, and ultrathin shape. Fluorescent and phosphorescent materials that are being applied to white OLEDs have been categorized, and the chemical structures and device performances of the important blue, orange, and red light-emitting materials have been summarized. Such a systematic classification and understanding of the materials that have already been reported can aid the development and study of new light-emitting materials through quantitative and qualitative approaches.

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Deep-Blue Phosphorescence from Perfluoro Carbonyl-Substituted Iridium Complexes

Cited by 248 publications

References 44 publications

Influences of fluorination on homoleptic iridium complexes with C∧N=N type ligand to material properties, ligand orientation and OLED performances

Influences of fluorination on homoleptic iridium complexes with C∧N=N type ligand to material properties, ligand orientation and OLED performances

Non-interlayer and color stable WOLEDs with mixed host and incorporating a new orange phosphorescent iridium complex

Recent progress in the use of fluorescent and phosphorescent organic compounds for organic light-emitting diode lighting

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