0000000000512830

AUTHOR

Md. K. Nazeeruddin

showing 7 related works from this author

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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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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Dual-emitting Langmuir-Blodgett film-based organic light-emitting diodes.

2010

Langmuir-Blodgett (LB) films containing alternating layers of the metallosurfactants bis(4,4'-tridecyl-2,2'-bipyridine)-(4,4'-dicarboxy-2,2'-bipyridine) ruthenium(II)-bis(chloride) (1) and bis[2-(2,4-difluorophenyl)pyridine](4,4'-dinonadecyl-2,2'-bipyridine)iridium(III) chloride (2) have been prepared. Langmuir monolayers at the air-water interface of 1 and 2 with different anions in the subphase have been characterized by pi-A compression isotherms and Brewster angle microscopy (BAM). The transferred LB films have been characterized by IR, UV-vis and emission spectroscopy, and atomic force microscopy (AFM). Electroluminescent devices formed by LB films containing alternating layers of thes…

Chemistrychemistry.chemical_elementSurfaces and InterfacesElectroluminescenceCondensed Matter PhysicsLangmuir–Blodgett filmRutheniumBipyridinechemistry.chemical_compoundCrystallographyMonolayerElectrochemistryOLEDOrganic chemistryGeneral Materials ScienceIridiumLayer (electronics)SpectroscopyLangmuir : the ACS journal of surfaces and colloids
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Origin of the large spectral shift in electroluminescence in a blue light emitting cationic iridium(III) complex

2007

A new, but archetypal compound [ Ir( ppy- F-2) (2)Me(4)phen] PF6, where ppy- F2 is 2-(2',4'- fluorophenyl) pyridine and Me(4)phen is 3,4,7,8- tetramethyl- 1,10- phenanthroline, was synthesized and used to prepare a solid-state light-emitting electrochemical cell (LEEC). This complex emits blue light with a maximum at 476 nm when photoexcited in a thin film, with a photoluminescence quantum yield of 52%. It yields an efficient single-component solid-state electroluminescence device with a current efficiency reaching 5.5 cd A(-1) and a maximum power efficiency of 5.8 Lm Watt(-1). However, the electroluminescence spectrum is shifted with respect to the photoluminescence spectrum by 80 nm resul…

education.field_of_studyFunctional Response TheoryPhotoluminescenceExcitation-EnergiesTransition-Metal-ComplexesChemistryPopulationQuantum yieldSolid-StateGeneral ChemistryExcited-State PropertiesElectroluminescencePhotochemistryOptical SpectroscopyExcited stateMaterials ChemistryLight emissionEmission spectrumElectrochemical-CellsTriplet stateeducationRoom-TemperatureSingle-LayerPhotophysical Properties
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Reversible Colorimetric Probes for Mercury Sensing

2005

The selectivity and sensitivity of two colorimetric sensors based on the ruthenium complexes N719 [bis(2,2'-bipyridyl-4,4'-dicarboxylate)ruthenium(II) bis(tetrabutylammonium) bis(thiocyanate)] and N749 [(2,2':6',2' '-terpyridine-4,4',4' '-tricarboxylate)ruthenium(II) tris(tetrabutylammonium) tris(isothiocyanate)] are described. It was found that mercury ions coordinate reversibly to the sulfur atom of the dyes' NCS groups. This interaction induces a color change in the dyes at submicromolar concentrations of mercury. Furthermore, the color change of these dyes is selective for mercury(II) when compared with other ions such as lead(II), cadmium(II), zinc(II), or iron(II). The detection limit…

IronInorganic chemistrychemistry.chemical_elementBiosensing TechniquesBiochemistrySensitivity and SpecificityCatalysischemistry.chemical_compoundColloid and Surface ChemistryIsothiocyanatesOrganometallic CompoundsColoring AgentsIonsTitaniumAqueous solutionThiocyanateMolecular StructureChemistryGeneral ChemistryMercuryChemical sensorTransition metal ionsMercury (element)RutheniumZincLeadRuthenium CompoundsColorimetrySpectrophotometry UltravioletSelectivityThiocyanatesCadmium
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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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Correlating the Lifetime and Fluorine Content of Iridium(III) Emitters in Green Light-Emitting Electrochemical Cells

2013

In light-emitting electrochemical cells, the lifetime of the device is intrinsically linked to the stability of the phosphorescent emitter. In this study, we present a series of ionic iridium(III) emitters based on cyclometalating phenylpyridine ligands whose fluorine substituents are varied in terms of position and number. Importantly, despite these structural modifications, the emitters exhibit virtually identical electrochemical and spectroscopic properties, which allows for proper comparison in functional devices. Quantum chemical calculations support the properties measured in solution and suggest great similarities regarding the electronic structures of the emitters. In electrolumines…

Materials sciencebusiness.industryGeneral Chemical EngineeringIonic bondingchemistry.chemical_elementGeneral ChemistrystabilityElectroluminescenceGreen-lightiridium emittersElectrochemical cellchemistryMaterials ChemistryFluorinePhysics::Accelerator PhysicsOptoelectronicsIridiumbusinessPhosphorescenceelectroluminescent devicesCommon emitterChemistry of Materials
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