Photophysical Properties and OLED Applications of Phosphorescent Platinum(II) Schiff Base Complexes

Che, Chi‐Ming; Kwok, Chi‐Chung; Lai, Siu‐Wai; Rausch, Andreas F.; Finkenzeller, Walter J.; Zhu, Nianyong; Yersin, Hartmut

doi:10.1002/chem.200902183

Cited by 282 publications

(216 citation statements)

References 56 publications

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“…Nonetheless, our devices perform quite well in comparison to sublimed platinum(II) complexes with N^C^N tridentate ligands (h c,max = 15-40 cd A À1 , L max = 3500-12 100 cd m À2 ) [16] or O^N^N^O Schiff base tetradentate units (h c,max = 1.6-31 cd A À1 , L max = 3000-20 000 cd m À2 ). [17] The efficiency of small-molecule OLEDs is higher owing to a more sophisticated device configuration. However, solution-processable emitters would enable a cost-effective fabrication.…”

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confidence: 99%

Switching On Luminescence by the Self‐Assembly of a Platinum(II) Complex into Gelating Nanofibers and Electroluminescent Films

et al. 2010

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Triplet emitters based on platinum(II) complexes have gained major attention in recent times.[1] They can form aggregates or excimers, causing shifts in the emitted wavelengths and affecting the photoluminescence quantum yields (PLQYs). [2] Even though this effect can be exploited for the construction of white organic light emitting diodes (WOLEDs), [3] it is disadvantageous for applications where color purity is desirable. Terpyridine ligands [4] and their N^C^N and N^N^C analogues [5] have been coordinated to platinum(II), leading to neutral, mono-, or doubly charged species, some of which display bright luminescence. They can form supramolecular structures, such as nanowires, nanosheets, and polymeric mesophases, with interesting optical properties.[6]For low-molecular-weight organo-or hydrogelators, [7] the operating mechanism of gelation has been recognized as a supramolecular effect, where the constituting fibers, usually of microscale lengths and nanoscale diameters, are formed in solution predominantly by unidirectional self-assembly.[8] The entanglement of filaments gives a network that entraps solvent molecules within the compartments. As supramolecular gels provide fibrous aggregates with long-range order, they could be of interest in the fields of optoelectronic devices and sensors. In this context, organometallic gelators can display metal-metal interactions that influence their properties.[9]Herein we present a straightforward one-pot synthesis of neutral, soluble platinum(II) coordination compounds bearing a dianionic tridentate terpyridine-like ligand. The coordination of an alkyl pyridine ancillary moiety to the 2,6-bis(tetrazolyl)pyridine complex allowed us to enhance the solubility and thus the processability. The synthetic approach involved mild reaction conditions that involved a nonnucleophilic base and an adequate inorganic platinum(II) precursor. Moisture-and oxygen exclusion were not required, and the product was easily purified by repeated precipitation (Scheme 1). The emission intensity of the complex attained a PLQY of up to 87 % in thin films, with concentrationindependent color and efficiency. We demonstrated its suitability as a dopant in solution-processed OLEDs. Furthermore, we discovered that this complex is also able to selfassemble into bright nanofibers, which can interlock to yield highly emissive gels (90 % PLQY), thus constituting a versatile building block for luminescent supramolecular architectures. Scheme 1. One-pot synthesis of platinum(II) complex 4 and a representation of the self-assembly process, going from luminescent aggregates to fibers and gels.

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confidence: 99%

Switching On Luminescence by the Self‐Assembly of a Platinum(II) Complex into Gelating Nanofibers and Electroluminescent Films

et al. 2010

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“…[17] Die Effizienz von OLEDs mit kleinen Molekülen ist wegen ihrer anspruchsvollen Struktur höher, doch würden in Lösung prozessierbare Emitter eine kostengünstigere Herstellung ermöglichen.…”

Section: Sublimation Hergestellt Wurden Und Ptunclassified

Lumineszenz eines Platin(II)‐Komplexes in gelierenden Nanofasern und elektrolumineszierenden Filmen

et al. 2010

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“…The doping rate of the emissive layer plays a key role in the efficiency and the color emission of devices. It was demonstrated that the device efficiency increased with a concentration of platinum (II) dopant, up to 5 wt % or 6 wt % depending on the platinum(II) complex [16]. By considering a 6 wt % concentration of [Pt] (with Alq3 number density ~10 21 cm −3 [17]) and by assuming that the Ptcomplexes do not aggregate, the number density of Pt-complex is estimated at about 6.10 19 [Pt]/cm 3 and the average distance between neighboring complexes at ~ 3 nm.…”

Section: Host-guest Systemmentioning

confidence: 99%

“…Thereby, the effective distance over which the energy transfers between complexes (estimated at 3 nm) would be higher than the radius of triplet-triplet annihilation (<1 nm through Dexter mechanism) [18][19][20]. Furthermore, the steric hindrance between adjacent molecules induced by the tert-butyl substituents of [Pt] tends to limit the formation of [Pt] aggregates and hence reduces aggregation-induced phosphorescence quenching in thin solid film [15,16]. Consequently, doping rate of [Pt] is fixed at 6 wt % to maximize the performance of the devices.…”

Section: Host-guest Systemmentioning

confidence: 99%

“…Based on C. Che et al research on phosphorescent Pt(II) Schiff Base complexes [16], we synthetized [Pt(II)(tetra-tert-butylsalophen)] named [Pt] (Scheme 1) which is thermally stable (Td = 390 • C). Time-dependent density functional theory (TD-DFT) calculations [15] have been performed in order to assign the different electronic transition of [Pt].…”

Section: Host-guest Systemmentioning

confidence: 99%

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Application of [Pt(II)(Tetra-Tert-Butylsalophen)] Complex within Organic Devices: Deep Red Emission, Bistable Light-Emitting Diodes and Operational Stability

et al. 2018

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This paper focuses on the Negative Differential Resistance (NDR) we observed on organic light-emitting diodes (OLEDs) using [Pt(II)(tetra-tert-butylSalophen)] as host, since this Pt(II) complex displays a deep-red emission (λ max = 660 nm). Electrical characterizations of monolayer devices have shown that doping Tris-(8-hydroxyquinoline)aluminum (Alq 3 ) as matrix emissive layer with this complex, leads to the modulation of the charge transport properties highlighted by Negative Differential Resistance (NDR). Upon electrical driving stresses, the conductivity of active layer can be switched between two electrical states (ON and OFF) with a figure of merit higher than 10 3 . By adding an electron-blocking layer, we demonstrated that the NDR trend is closely related to negative charge accumulation within Alq 3 leading to the modification of electronic properties in the vicinity of anode/active layer interface. The NDR phenomenon is interpreted in terms of space charge polarization (SCP) linked to charge trapping/untrapping mechanism as a consequence of the polarization/depolarization of the Pt(II) complex. Under electrical driving stresses, the performance of the devices which include the Pt(II) complex, are stabilized. A schematic model is proposed to depict the SCP responsible for NDR and decrease-resetting behaviors observed in these devices.

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Photophysical Properties and OLED Applications of Phosphorescent Platinum(II) Schiff Base Complexes

Cited by 282 publications

References 56 publications

Switching On Luminescence by the Self‐Assembly of a Platinum(II) Complex into Gelating Nanofibers and Electroluminescent Films

Switching On Luminescence by the Self‐Assembly of a Platinum(II) Complex into Gelating Nanofibers and Electroluminescent Films

Lumineszenz eines Platin(II)‐Komplexes in gelierenden Nanofasern und elektrolumineszierenden Filmen

Application of [Pt(II)(Tetra-Tert-Butylsalophen)] Complex within Organic Devices: Deep Red Emission, Bistable Light-Emitting Diodes and Operational Stability

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