Search results for "Indium selenide"

showing 6 items of 6 documents

Experimental and Theoretical Studies on alfa-In2Se3 at High Pressure

2018

[EN] alpha(R)-In2Se3 has been experimentally and theoretically studied under compression at room temperature by means of X-ray diffraction and Raman scattering measurements as well as by ab initio total-energy and lattice-dynamics calculations. Our study has confirmed the alpha (R3m) -> beta' (C2/m) ? beta (R (3) over barm) sequence of pressure-induced phase transitions and has allowed us to understand the mechanism of the monoclinic C2/m to rhombohedral R (3) over barm phase transition. The monoclinic C2/m phase enhances its symmetry gradually until a complete transformation to the rhombohedral R (3) over barm structure is attained above 10-12 GPa. The second-order character of this transi…

DiffractionPhase transitionHigh-pressureAb initio02 engineering and technology01 natural sciencesInorganic ChemistryCondensed Matter::Materials Sciencesymbols.namesake0103 physical sciencesPhysical and Theoretical Chemistry010306 general physicsRamanPhase transitionIndium selenideChemistry021001 nanoscience & nanotechnologySymmetry (physics)X-ray diffractionCrystallographyFISICA APLICADAX-ray crystallographyAb initiosymbols0210 nano-technologyRaman spectroscopyRaman scatteringMonoclinic crystal system
researchProduct

High‐temperature behavior of impurities and dimensionality of the charge transport in unintentionally and tin‐doped indium selenide

1993

A systematic study of the electron transport and shallow impurity distribution in indium selenide above room temperature or after an annealing process is reported by means of far‐infrared‐absorption and Hall‐effect measurements. Evidences are found for the existence of a large concentration of deep levels (1012–1013 cm−2), related to impurities adsorbed to stacking faults in this material. Above room temperature impurities can migrate from those defect zones and then become shallow in the bulk. The subsequent large increase of 3D electrons can change the dimensionality of the electron transport, which in most cases was 2D. The temperature dependence of the resistivity parallel to the c axis…

Electron mobilityInfrared SpectraAnnealing (metallurgy)Analytical chemistryGeneral Physics and Astronomychemistry.chemical_elementAnnealingchemistry.chemical_compound:FÍSICA [UNESCO]Hall effectImpurityElectrical resistivity and conductivityTin AdditionsSelenideDoped MaterialsIndium SelenidesHall EffectCondensed matter physicsTemperature DependenceDopingUNESCO::FÍSICAElectric ConductivityIndium Selenides ; Tin Additions ; Impurities ; Annealing ; Electric Conductivity ; Infrared Spectra ; Hall Effect ; Deep Energy Levels ; Temperature Dependence ; Doped MaterialsDeep Energy LevelschemistryIndiumImpuritiesJournal of Applied Physics
researchProduct

Photoconductivity and photovoltaic effect in indium selenide

1983

Transport and phototransport properties of crystalline indium monoselenide (InSe) doped with a variety of elements are reported. Measured mobilities, lifetimes, and effective diffusion lengths of photoexcited carriers are used to interpret electrical and photovoltaic properties of several different structures. These include p‐n junctions, bismuth/p‐type InSe, platinum/n‐type InSe, and indium tin oxyde (ITO)/p‐type InSe. External solar efficiencies of the best devices are between 5% and 6%. The influence on the efficiency of the various parameters is evaluated, and ways of improvement are discussed.

Materials sciencePhotoconductivityInorganic chemistryN−Type ConductorsGeneral Physics and Astronomychemistry.chemical_elementPhotovoltaic effectIndium CompoundsEfficiencyCrystalsBismuthPhotovoltaic EffectCharge Carrierschemistry.chemical_compoundP−Type ConductorsIndium Selenides ; Photoconductivity ; Photovoltaic Effect ; Experimental Data ; Crystals ; Doped Materials ; Mobility ; Lifetime ; Diffusion Length ; Charge Carriers ; Electrical Properties ; P−N Junctions ; P−Type Conductors ; N−Type Conductors ; Bismuth ; Platinum ; Indium Compounds ; Tin Oxides ; Efficiency:FÍSICA [UNESCO]SelenideDoped MaterialsPlatinumMobilityIndium Selenidesbusiness.industryPhotoconductivityElectrical PropertiesDopingP−N JunctionsUNESCO::FÍSICATin OxidesDiffusion LengthchemistryOptoelectronicsExperimental DataCharge carrierTinbusinessBismuthIndiumLifetime
researchProduct

Nanotexturing To Enhance Photoluminescent Response of Atomically Thin Indium Selenide with Highly Tunable Band Gap.

2016

Brotons-Gisbert, Mauro et al.

MicrophotoluminescenceMaterials sciencePhotoluminescenceBand gapchemistry.chemical_elementBioengineeringNanotechnology02 engineering and technologyTwo-dimensional materials010402 general chemistry01 natural sciencesCondensed Matter::Materials Sciencechemistry.chemical_compoundSelenideGeneral Materials ScienceIndium selenideOptical propertiesbusiness.industryMechanical EngineeringMetamaterialGeneral ChemistryCondensed Matter::Mesoscopic Systems and Quantum Hall Effect021001 nanoscience & nanotechnologyCondensed Matter PhysicsNanotexturing0104 chemical sciencesSemiconductorchemistryQuantum dotBand gap engineering0210 nano-technologybusinessIndiumVisible spectrumNano letters
researchProduct

Electrical and photovoltaic properties of indium‐tin‐oxide/p‐InSe/Au solar cells

1987

Conditions for efficiency improvement and optimization in indium‐tin‐oxide/p‐indium‐selenide solar cells are discussed in this paper. This aim is achieved by using low‐resistivity p‐indium‐selenide and by incorporating a back‐surface‐field contact. This contact is insured by a p‐indium selenide/gold barrier whose rectifying behavior is explained through the complex impurity structure of p‐indium‐selenide. Electrical and photovoltaic properties of the cells are also reported. The efficiency parameters under AM1 simulated conditions have been improved up to 32 mA/cm2 for the short‐circuit current density, 0.58 V for the open‐circuit voltage, and 0.63 for the filling factor. As a result, solar…

OptimizationMaterials sciencePerformanceIndium OxidesGeneral Physics and Astronomychemistry.chemical_elementEfficiencyPhotovoltaic effectIndium Selenide Solar CellsPhotovoltaic Effectchemistry.chemical_compound:FÍSICA [UNESCO]Selenidebusiness.industryElectrical PropertiesOptimization ; Efficiency ; Indium Selenide Solar Cells ; Performance ; Indium Oxides ; Tin Oxides ; Photovoltaic Effect ; Electrical Properties ; Experimental DataPhotovoltaic systemEnergy conversion efficiencyUNESCO::FÍSICATin OxidesSolar energyIndium tin oxidechemistryExperimental DataOptoelectronicsbusinessCurrent densityIndiumJournal of Applied Physics
researchProduct

The application of the photoacoustic transmittance oscillations for determining elastic constants in gallium and indium selenides

1996

Transmittance periodic oscillations are observed in GaSe and InSe on excitation with optical pulses. Such oscillations are explained in terms of photoacoustic generation of dilatational waves, which become resonant within the crystal. Spectral analysis of those oscillations in samples of different thickness has led to an accurate determination of the longitudinal acoustic‐wave velocity along the crystallographic axis c. Julio.Pellicer@uv.es ; Chantal.Ferrer@uv.es ; Vicente.Munoz@uv.es

OscillationsGallium SelenidesGeneral Physics and Astronomychemistry.chemical_elementPhotoacoustic imaging in biomedicineMonocrystalsMolecular physicsResonanceCrystalOptics:FÍSICA [UNESCO]TransmittanceGallium Selenides ; Indium Selenides ; Monocrystals ; Oscillations ; Photoacoustic Effect ; Resonance ; Sound Velocity ; Sound WavesSound VelocityGalliumSound WavesPhotoacoustic effectPhotoacoustic EffectIndium Selenidesbusiness.industryUNESCO::FÍSICAResonancechemistrybusinessExcitationIndium
researchProduct