Search results for " Iridium"

showing 6 items of 6 documents

White-light phosphorescence emission from a single molecule: application to OLED.

2009

A simple mononuclear cyclometallated iridium(III) complex exhibits white photo- and electro- luminescence in the wavelength range from 440 to 800 nm, which originates from a single emitting excited state of mixed character. Bolink Henk, Henk.Bolink@uv.es ; Coronado Miralles, Eugenio, Eugenio.Coronado@uv.es

DesignLuminescenceUNESCO::QUÍMICAAb initioColorchemistry.chemical_elementEfficiency010402 general chemistryPhotochemistry:QUÍMICA [UNESCO]01 natural sciencesCatalysisCopolymerIridium ComplexesMaterials ChemistryOLEDMoleculeIridiumDiodeEmitting DevicesMononuclear cyclometallated iridiumPhosphorescence010405 organic chemistryChemistrybusiness.industryUNESCO::QUÍMICA::Química analíticaMetals and AlloysAb-InitioGeneral ChemistryDiodes0104 chemical sciences3. Good healthSurfaces Coatings and FilmsElectronic Optical and Magnetic MaterialsBlueOLEDExcited stateGreen:QUÍMICA::Química analítica [UNESCO]Ceramics and CompositesOptoelectronicsMononuclear cyclometallated iridium ; Luminescence ; Phosphorescence ; OLEDLuminescencePhosphorescencebusinessChemical communications (Cambridge, England)
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Photophysical Properties of Charged Cyclometalated Ir(III) Complexes: A Joint Theoretical and Experimental Study

2011

The photophysical properties of a series of charged biscyclometalated [Ir(ppy)(2)(N boolean AND N)](1+) complexes, where ppyH is 2-phenylpyridine and N boolean AND N is 2,2'-bipyridine (bpy), 6-phenyl-2,2'-bipyridine (pbpy), and 6,6'-dipheny1-2,2'-bipyridine (dpbpy) for complexes 1, 2, and 3, respectively, have been investigated in detail. The photoluminescence performance in solution decreases from 1 to 3 upon attachment of phenyl groups to the ancillary ligand. The absorption spectra recorded over time suggest that complex 3 is less stable compared to complexes 1 and 2 likely due to a nucleophilic-assisted ancillary ligand-exchange reaction. To clarify this behavior, the temperature depen…

ELECTROLUMINESCENT DEVICESPhotoluminescenceAbsorption spectroscopyEMITTING ELECTROCHEMICAL-CELLSLigandChemistryCATIONIC IRIDIUM COMPLEXESAnalytical chemistryLARGE MOLECULESTURN-ON TIMESTRANSITION-METAL-COMPLEXESInorganic ChemistryCONCENTRATION GRADIENTSReaction rate constantTEMPERATURE-DEPENDENCEQUANTUM YIELDSPhysical chemistryPhysical and Theoretical ChemistryENERGY-GAP LAWInorganic Chemistry
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Luminescent Ionic Transition-Metal Complexes for Light-Emitting Electrochemical Cells

2012

Higher efficiency in the end-use of energy requires substantial progress in lighting concepts. All the technologies under development are based on solid-state electroluminescent materials and belong to the general area of solid-state lighting (SSL). The two main technologies being developed in SSL are light-emitting diodes (LEDs) and organic light-emitting diodes (OLEDs), but in recent years, light-emitting electrochemical cells (LECs) have emerged as an alternative option. The luminescent materials in LECs are either luminescent polymers together with ionic salts or ionic species, such as ionic transition-metal complexes (iTMCs). Cyclometalated complexes of Ir(III) are by far the most util…

IonsMaterials scienceLuminescenceLightMolecular StructureIonic bondingNanotechnologycopper(I) complexes; electroluminescence; iridium(III) complexes; light-emitting electrochemical cells; ruthenium(II) complexesGeneral ChemistryElectrochemical TechniquesElectroluminescenceCatalysisElectrochemical celllaw.inventionTransition metallawOLEDOrganometallic CompoundsTransition ElementsLuminescenceLight-emitting diodeDiode
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Highly phosphorescent perfect green emitting iridium(iii) complex for application in OLEDs.

2007

A novel iridium complex, [bis-(2-phenylpyridine)(2-carboxy-4-dimethylaminopyridine)iridium(III)] (N984), was synthesized and characterized using spectroscopic and electrochemical methods; a solution processable OLED device incorporating the N984 complex displays electroluminescence spectra with a narrow bandwidth of 70 nm at half of its intensity, with colour coordinates of x = 0.322; y = 0.529 that are very close to those suggested by the PAL standard for a green emitter. Bolink, Henk, Henk.Bolink@uv.es ; Coronado Miralles, Eugenio, Eugenio.Coronado@uv.es ; Garcia Santamaria, Sonsoles Amor, Sonsoles.Garcia@uv.es

Materials sciencePhosforescenseUNESCO::QUÍMICAchemistry.chemical_elementNanotechnologyIridiumElectrochemistry:QUÍMICA [UNESCO]CatalysisNarrow bandwidthSpectrostopic methodElectrochemical methodMaterials ChemistryOLEDIridiumElectroluminescence spectraCommon emitterbusiness.industryUNESCO::QUÍMICA::Química analíticaMetals and AlloysGeneral ChemistryPhosforescense ; Green ; Iridium ; OLED ; Spectrostopic method ; Electrochemical methodSurfaces Coatings and FilmsElectronic Optical and Magnetic MaterialsOLEDchemistryGreen:QUÍMICA::Química analítica [UNESCO]Ceramics and CompositesOptoelectronicsbusinessPhosphorescenceChemical communications (Cambridge, England)
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The Cryogenic AntiCoincidence Detector Project for ATHENA+: An Overview Up to the Present Status

2014

ATHENA+ is a space mission proposal for the next ESA L2-L3 slot. One of the focal plane instruments is the X-ray integral field unit (X-IFU) working in the energy range 0.3–10 keV. It is a multi-array based on TES detectors aimed at characterizing faint or diffuse sources (e.g. WHIM or galaxy outskirt). The X-IFU will be able to achieve the required sensitivity if a low background is guaranteed. The studies performed by GEANT4 simulations depict a scenario where the use of an active anticoincidence (AC) is mandatory to reduce the background expected in L2 orbit down to the goal level of 0.005 cts cm $$^{-2}$$  s $$^{-1}$$  keV $$^{-1}$$ . This is possible using a cryogenic anticoincidence (…

PhysicsSiliconbusiness.industryAnticoincidence detectorDetectorOrder (ring theory)SpaceTES Silicon Iridium Anticoincidence detector SpaceIridiumCondensed Matter PhysicsAtomic and Molecular Physics and OpticsGalaxyOpticsCardinal pointAnticoincidence detector; Iridium; Silicon; Space; TES; Atomic and Molecular Physics and Optics; Materials Science (all); Condensed Matter PhysicsSettore FIS/05 - Astronomia E AstrofisicaAtomic and Molecular PhysicsOrbit (dynamics)General Materials ScienceSensitivity (control systems)Materials Science (all)and OpticsbusinessTESEnergy (signal processing)
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An inconvenient influence of iridium(III) isomer on OLED efficiency.

2010

The recently reported heteroleptic cyclometallated iridium(III) complex [Ir(2-phenylpyridine)(2)(2-carboxy-4-dimethylaminopyridine)] N984 and its isomer N984b have been studied more in detail. While photo- and electrochemical properties are very similar, DFT/TDDFT calculations show that the two isomers have different HOMO orbital characteristics. As a consequence, solution processed OLEDs made using a mixture of N984 and isomer N984b similar to vacuum processed devices show that the isomer has a dramatic detrimental effect on the performances of the device. In addition, commonly used thermogravimetric analysis is not suitable for showing the isomerization process. The isomer could impact pe…

Thermogravimetric analysisInjectionMaterials scienceLightchemistry.chemical_elementTransportElectrochemistryPhotochemistryIridiumlaw.inventionPhosphorescent OledsInorganic ChemistryIsomerismComplexeslawOLEDElectrochemistryOrganometallic CompoundsDevicesIridiumDopantMolecular StructureConversionTime-dependent density functional theorychemistryElectrochemistry; Iridium; Isomerism; Molecular Structure; Organometallic Compounds; Light; Quantum TheoryGreenQuantum TheoryBipolar HostIsomerizationLight-emitting diodeLight-Emitting-Diodes
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