Search results for "molecular semiconductors"

showing 4 items of 4 documents

Les matériaux pour capteurs chimiques

2002

National audience; A chemical sensor is composed of one part supplying chemical reco gnition coupled to one transducingsystem. At the recognition origin, interaction with the target chemical species is oftwo types, either electronicexchange, or ionic exchange. Two large classes of materials that can supply recognition proceed: metals andsemiconductors giving rise to electronic exchange and ionic conducting materials giving rise to ionic exchan-ge. This paper is structured in tw o large parts, emphasizing on materi als inducing specific interactions:semiconductor materials (metallic oxides and molecular semiconductors) and ionic conductor materials.In each part will be presented nature of ma…

[SPI.GPROC] Engineering Sciences [physics]/Chemical and Process Engineeringoxydes métalliques[ SPI.GPROC ] Engineering Sciences [physics]/Chemical and Process Engineering[SPI.GPROC]Engineering Sciences [physics]/Chemical and Process EngineeringCapteurs de gazmolecular semiconductorssemi-conducteurs moléculairesionic conductor materialsGas sensorsmetallic oxidesmatériaux conducteurs ioniquescapteurs ioniquesionic sensors
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Bias and humidity effects on the ammonia sensing of perylene derivative/lutetium bisphthalocyanine MSDI heterojunctions

2016

International audience; In this paper, we prepared and studied sensors based on Molecular Semiconductor-Doped Insulator (MSDI) heterojunctions. These original devices are built with two stacked layers of molecular materials and exhibit very specific electrical and sensing properties. We studied the properties of a MSDI composed of the perylenetetracarboxylic dianhydride, PTCDA, or the fluorinated perylenebisimine derivative, C4F7-PTCDI, as n-type molecular material sublayers, and LuPc2 as a p-type semiconductor top layer. Their response to ammonia was compared to that of a resistor formed of only the top layer of the MSDI (LuPc2). Ammonia increases the current in the MSDIs whereas it causes…

MSDIAir quality monitoringAbsorption spectroscopyInorganic chemistryAnalytical chemistryConductometric sensor02 engineering and technology010402 general chemistrysensors[ CHIM ] Chemical Sciences01 natural sciencesLangmuir–Blodgett filmchemistry.chemical_compoundAmmoniaMaterials Chemistry[CHIM]Chemical SciencesRelative humiditygas sensitivitymolecular semiconductorsElectrical and Electronic EngineeringThin filmPerylenetetracarboxylic dianhydrideInstrumentationelectrical-propertiesabsorption-spectracomplexesbusiness.industryfield-effect transistorsMetals and AlloysHeterojunctionRelative humidity021001 nanoscience & nanotechnologyCondensed Matter Physics0104 chemical sciencesSurfaces Coatings and FilmsElectronic Optical and Magnetic MaterialsphthalocyanineSemiconductorchemistryOrganic heterojunctionthin-filmslangmuir-blodgett0210 nano-technologybusinessPerylene
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Measurement of drift mobilities in amorphous organic films using the Time of Flight method

2004

We apply the Time of Flight (TOF) technique to study carrier mobility in N, N’-diphenyl-N,N’-bis(3-methylphenyl) -1,1-biphenyl-4,4’-diamine (TPD) and tris(8-hydroxyquinolato) aluminium (Alq 3 ). These materials are two examples of, respectively, hole and electron transporting molecular materials. Measurements are performed in free air or under vacuum varying the experimental parameters such as laser pulse intensity and single shot irradiation. We observe a transition from dispersive to non dispersive transport changing the experimental conditions.

Electron mobilityAnalytical chemistrychemistry.chemical_elementElectronLaserTime of Flight (TOF) charge carrier mobility organic molecular semiconductorsSettore ING-INF/01 - ElettronicaAmorphous solidlaw.inventionTime of flightchemistryAluminiumlawIrradiationPulse intensity
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Research data supporting the paper "Tuning the effective spin-orbit coupling in molecular semiconductors"

2017

We here present the data underlying the paper "Tuning the effective spin-orbit coupling in molecular semiconductors" accepted at Nature Communications on 24 February 2017. For contributions of the authors to the data and experimental details, please refer to the original paper.

Spin orbit couplingOrganic semiconductorsSpintronicsMolecular semiconductorsOrganic spintronics
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