Search results for "Conducting polymers"

showing 10 items of 17 documents

ELECTROCHEMICAL FABRICATION OF METAL/OXIDE/CONDUCTING POLYMER JUNCTIONS FOR ELECTRONIC DEVICES

2014

Electrochemical fabrication metal/oxide/conducting polymer junctions electronic devicesSettore ING-IND/23 - Chimica Fisica ApplicataSOLID STATE ELECTROLYTIC CAPACITORS FIELD EFFECT TRANSISTORS ANODIC OXIDES CONDUCTING POLYMERS PHOTOELECTROCHEMISTRY ELECTROCHEMICAL IMPEDANCE SPECTROSCOPY PEDOT NIOBIUM OXIDE TITANIUM OXIDE TANTALUM OXIDE
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From monolayer to multilayer N-channel polymeric field-effect transistors with precise conformational order

2012

Monolayer field-effect transistors based on a high-mobility n-type polymer are demonstrated. The accurate control of the long-range order by Langmuir-Schafer (LS) deposition yields dense polymer packing exhibiting good injection properties, relevant current on/off ratio and carrier mobility in a staggered configuration. Layer-by-layer LS film transistors of increasing thickness are fabricated and their performance compared to those of spin-coated films.

Electron mobilityMaterials scienceTransistors ElectronicPolymersNanotechnologyThiophenesNaphthalenesTransistorslaw.inventionlawMonolayerElectronicDeposition (phase transition)General Materials Sciencemonolayer field-effect transistorchemistry.chemical_classificationbusiness.industrysemiconducting polymersMechanical EngineeringTransistorTransistor monolayer polymers orderPolymercharge transportchemistrylayered materialsMechanics of MaterialsN channelOptoelectronicsField-effect transistorbusiness
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Ionic and Free Solvent Motion in Poly(azure A) Studied by ac-Electrogravimetry

2011

International audience; This work is focused on the mechanistic aspects of the redox behavior of poly(azure A) taking advantage of the controlled modulation of their oxidation states by ac-electrogravimetry. The originality of this technique is its ability to discriminate between cation and anion involved in the charge compensation process and the accompanying free solvent transfer, directly or indirectly. Two processes were proposed where the faster ionic exchange is considered to be the participation of the anion species acting as counterions whereas the slower one is related to the proton transfer. The proton is implied as reactants for the two electroactive sites identified in the polym…

Inorganic chemistryIonic bondingAzure A02 engineering and technology010402 general chemistry01 natural sciencesRedoxIonchemistry.chemical_compoundQUARTZ-CRYSTAL MICROBALANCEElectrogravimetryPOLYMER-MODIFIED ELECTRODESPhysical and Theoretical ChemistryELECTROACTIVE THIN-FILMSchemistry.chemical_classificationAqueous solutionPRUSSIAN BLUE021001 nanoscience & nanotechnologyPOLY(NEUTRAL RED)0104 chemical sciencesSurfaces Coatings and FilmsElectronic Optical and Magnetic MaterialsSolventGeneral EnergyELECTROCHEMICAL POLYMERIZATIONTECHNIQUES ELECTRICAL CHARGEchemistryCONDUCTING POLYMERSCounterion[CHIM.OTHE]Chemical Sciences/Other0210 nano-technologyELECTROPOLYMERIZED AZINESINNOVATIVE COMBINATIONThe Journal of Physical Chemistry C
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Poly(alkoxyphenylene-thienylene) Langmuir-Schäfer thin-films for advanced performance transistors

2005

Solution processed Langmuir-Scha ̈fer and cast thin films of regioregular poly(2,5-dioctyloxy-1,4- phenylene-alt-2,5-thienylene) are investigated as transistor active layers. The study of their field-effect properties evidences that no transistor behavior can be seen with a cast film channel material. This was not surprising considering the twisted conformation of the polymer backbone predicted by various theoretical studies. Strikingly, the Langmuir-Scha ̈fer (LS) thin films exhibit a field-effect mobility of 5 × 10-4 cm2/V‚s, the highest attained so far with an alkoxy-substituted conjugated polymer. Extensive optical, morphological, and structural thin-film characterization supports the a…

LangmuirMaterials sciencePHENYLENEGeneral Chemical EngineeringNanotechnologylaw.inventionlawPhenyleneSTILLE COUPLING REACTIONMaterials ChemistryThin filmConductive polymerbusiness.industryREGIOREGULAR POLY(3-HEXYLTHIOPHENE)TransistorGeneral ChemistryOPTICAL-PROPERTIESSolution processedBLODGETT-FILMSCONDUCTING POLYMERSOptoelectronicsField-effect transistorPOLYTHIOPHENESFIELD-EFFECT TRANSISTORSREPEAT UNITSbusinessCONJUGATED POLYMERS
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A Very Low Band Gap Diketopyrrolopyrrole-Porphyrin Conjugated Polymer

2017

International audience; A porphyrin-diketopyrrolopyrrole-containing polymer (poly(porphyrin-diketopyrrolopyrrole) (PPDPP)) shows impressive molar absorption coefficients from lambda=300 to 1000 nm. The photophysical and structural properties of PPDPP have been studied. With PPDPP as the electron donor and [ 6,6]phenyl C-71 butyric acid methyl ester (PC71BM) as the electron acceptor, the bulk heterojunction polymer solar cell showed overall power conversion efficiencies of 4.18 and 6.44% for as-cast and two-step annealing processed PPDPP: PC71BM (1: 2) active layers, respectively. These results are quite impressive for porphyrin-containing polymers, especially when directly included in the p…

Materials scienceBand gapbuilding-blockporphyrinoidsElectron donorthin-film transistors02 engineering and technologyConjugated system010402 general chemistryPhotochemistry[ CHIM ] Chemical Sciences01 natural sciencesPolymer solar cellheterojunction solar-cellschemistry.chemical_compound[CHIM]Chemical Sciencessmall-moleculepolymerschemistry.chemical_classificationsemiconducting polymerscharge transferGeneral ChemistryPolymerChromophoreElectron acceptorside-chains021001 nanoscience & nanotechnologyPorphyrinphotovoltaic properties0104 chemical sciencesphotodynamic therapychemistryorganic photovoltaics0210 nano-technologyabsorptionperformanceconjugationChemPlusChem
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Millisecond radiative recombination in poly(phenylene vinylene)-based light-emitting diodes from transient electroluminescence

2007

The current and electroluminescence transient responses of standard poly phenylene vinylene -based light-emitting devices have been investigated. The electroluminescence time response is longer milliseconds scale than the current switch-off time by more than one order of magnitude, in the case of small area devices 0.1 cm2 . For large area devices 6 cm2 the electroluminescence decay time decreases from 1.45 ms to 100 s with increasing bias voltage. The fast current decay limits the electroluminescence decay at higher voltages. Several approaches are discussed to interpret the observed slow decrease of electroluminescence after turning off the bias. One relies upon the Langevin-type bimolecu…

Materials scienceCarrier transportConducting polymersGeneral Physics and AstronomyOrganic light emitting diodesElectroluminescencelaw.inventionCurrent density:FÍSICA [UNESCO]lawPhenyleneOLEDSpontaneous emissionMinority carriersbusiness.industryUNESCO::FÍSICABiasingLight emitting diodesElectroluminescenceBias voltageElectron-hole recombinationOptoelectronicsElectron trapsbusinessConducting polymers ; Organic light emitting diodes ; Electron-hole recombination ; Electroluminescence ; Minority carriers ; Electron traps ; Current densityCurrent densityOrder of magnitudeLight-emitting diode
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Review on Polymers for Thermoelectric Applications.

2014

In this review, we report the state-of-the-art of polymers in thermoelectricity. Classically, a number of inorganic compounds have been considered as the best thermoelectric materials. Since the prediction of the improvement of the figure of merit by means of electronic confinement in 1993, it has been improved by a factor of 3-4. In the mean time, organic materials, in particular intrinsically conducting polymers, had been considered as competitors of classical thermoelectrics, since their figure of merit has been improved several orders of magnitude in the last few years. We review here the evolution of the figure of merit or the power factor during the last years, and the best candidates…

Materials scienceNanotechnologyReviewlcsh:TechnologyThermoelectric effectnanocompositesintrinsically conducting polymersFigure of meritGeneral Materials ScienceOrders of magnitude (data)lcsh:Microscopylcsh:QC120-168.85chemistry.chemical_classificationConductive polymerlcsh:QH201-278.5lcsh:TPolymerThermoelectric materialschemistrylcsh:TA1-2040Inorganic materialslcsh:Descriptive and experimental mechanicslcsh:Electrical engineering. Electronics. Nuclear engineeringlcsh:Engineering (General). Civil engineering (General)lcsh:TK1-9971thermoelectricsMaterials (Basel, Switzerland)
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Nanostructural depth-profile and field-effect properties of poly(alkoxyphenylene-thienylene) Langmuir-Schäfer thin-films

2008

The correlations between morphological features and field-effect properties of poly(alkoxyphenylene-thiophene) thin Langmuir–Schafer film deposited on differently terminated gate dielectric surfaces, namely bare and methyl functionalized thermal silicon dioxide (t-SiO2), have been systematically studied. The film morphology has been investigated at different film thickness by Scanning Force Microscopy. Films thicker than a few layers show comparable morphology on both dielectric surfaces while differences are seen for the ultra-thin polymer deposit in close proximity to the substrate. Such deposit is notably more heterogeneous on bare t-SiO2, while a more compact and uniform nanogranular st…

Materials scienceSiliconSilicon dioxideGate dielectricField effectchemistry.chemical_elementConducting polymersNanotechnologySubstrate (electronics)Dielectricchemistry.chemical_compoundMaterials ChemistryComposite materialThin filmConductive polymerLangmuir-Schäfer organic thin-filmsOrganic–inorganic interfaceConducting polymers; Langmuir-Schäfer organic thin-films; Organic field effect transistors; Organic-inorganic interfaceOrganic-inorganic interfaceConducting polymerLangmuir–Schäfer filmMetals and AlloysSurfaces and InterfacesSurfaces Coatings and FilmsElectronic Optical and Magnetic Materialstransistors thin films nanotechnology Langmuir-ShaeferchemistryOrganic field effect transistorsOrganic field effect transistor
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Controlling the mode of operation of organic transistors through side chain engineering

2016

Electrolyte-gated organic transistors offer low bias operation facilitated by direct contact of the transistor channel with an electrolyte. Their operation mode is generally defined by the dimensionality of charge transport, where a field-effect transistor allows for electrostatic charge accumulation at the electrolyte/semiconductor interface, whereas an organic electrochemical transistor (OECT) facilitates penetration of ions into the bulk of the channel, considered a slow process, leading to volumetric doping and electronic transport. Conducting polymer OECTs allow for fast switching and high currents through incorporation of excess, hygroscopic ionic phases, but operate in depletion mode…

Materials scienceTransconductanceNanotechnologyHardware_PERFORMANCEANDRELIABILITY02 engineering and technologyElectrolyte010402 general chemistry01 natural scienceslaw.inventionelectrochemical transistorlawMD MultidisciplinaryHardware_INTEGRATEDCIRCUITSSide chainConductive polymerMultidisciplinarySubthreshold conductionbusiness.industrysemiconducting polymersTransistor021001 nanoscience & nanotechnologyequipment and supplies0104 chemical sciencesorganic electronicsSemiconductorPhysical SciencesOptoelectronics0210 nano-technologybusinessHardware_LOGICDESIGNOrganic electrochemical transistor
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From Microorganism-Based Amperometric Biosensors towards Microbial Fuel Cells

2021

This review focuses on the overview of microbial amperometric biosensors and microbial biofuel cells (MFC) and shows how very similar principles are applied for the design of both types of these bioelectronics-based devices. Most microorganism-based amperometric biosensors show poor specificity, but this drawback can be exploited in the design of microbial biofuel cells because this enables them to consume wider range of chemical fuels. The efficiency of the charge transfer is among the most challenging and critical issues during the development of any kind of biofuel cell. In most cases, particular redox mediators and nanomaterials are applied for the facilitation of charge transfer from a…

Microbial fuel cellBioelectric Energy SourcesPolymersMicroorganismNanotechnologyBiosensing TechniquesReview02 engineering and technologyyeastbioelectronicslcsh:Chemical technology010402 general chemistry01 natural sciencesBiochemistryRedoxAnalytical ChemistryNanomaterialsmicrobial biosensorslcsh:TP1-1185microbial biofuel cells ; yeast ; direct electron transfer ; extracellular electron transfer ; cell membrane/wall modifications ; conducting polymers ; enzyme-based biofuel cells ; bioelectronics ; microbial biosensors ; whole cell-based biosensorsdirect electron transferenzyme-based biofuel cellsElectrical and Electronic EngineeringElectrodesconducting polymersInstrumentationwhole cell-based biosensorsConductive polymerBioelectronicsextracellular electron transferChemistryfungitechnology industry and agriculturefood and beveragesmicrobial biofuel cells021001 nanoscience & nanotechnologyAtomic and Molecular Physics and Optics0104 chemical sciencescell membrane/wall modificationsBiofuel0210 nano-technologyOxidation-ReductionBiosensorSensors
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