0000000000133822

AUTHOR

Giorgia Franzò

0000-0003-3630-0315

showing 6 related works from this author

Silicon-based light-emitting devices: Properties and applications of crystalline, amorphous and er-doped nanoclusters

2006

In this paper, we summarize the results of an extensive investigation on the properties of MOS-type light-emitting devices based on silicon nanostructures. The performances of crystalline, amorphous, and Er-doped Si nanostructures are presented and compared. We show that all devices are extremely stable and robust, resulting in an intense room temperature electroluminescence (EL) at around 900 nm or at 1.54 μm. Amorphous nanoclusters are more conductive than the crystalline counterpart. In contrast, nonradiative processes seem to be more efficient for amorphous clusters resulting in a lower quantum efficiency. Erbium doping results in the presence of an intense EL at 1.54 μm with a concomit…

Materials scienceSiliconElectroluminescent devicechemistry.chemical_elementNanocrystalQUANTUM DOTSElectroluminescenceSettore ING-INF/01 - ElettronicaSettore FIS/03 - Fisica Della MateriaNanoclustersErbiumIntegrated optoelectronicElectroluminescence (EL)Light-emitting deviceOptical interconnectionElectrical and Electronic Engineeringbusiness.industryDopingOPTICAL-PROPERTIESAtomic and Molecular Physics and OpticsAmorphous solid1.54 MU-MchemistryNanocrystalOptoelectronicsQuantum efficiencySI NANOCRYSTALSENERGY-TRANSFERbusinessErbium
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Carrier-induced quenching processes on the erbium luminescence in silicon nanocluster devices

2006

The luminescence-quenching processes limiting quantum efficiency in Er-doped silicon nanocluster light-emitting devices are investigated and identified. It is found that carrier injection, while needed to excite Er ions through electron-hole recombination, at the same time produces an efficient nonradiative Auger deexcitation with trapped carriers. This phenomenon is studied in detail and, on the basis of its understanding, we propose device structures in which sequential injection of electrons and holes can improve quantum efficiency by avoiding Auger processes. © 2006 The American Physical Society.

Materials scienceSiliconAstrophysics::High Energy Astrophysical Phenomenalight-emitting deviceschemistry.chemical_elementElectronElectroluminescenceSettore ING-INF/01 - ElettronicaSettore FIS/03 - Fisica Della MateriaAugerErbiumCondensed Matter::Materials ScienceELECTROLUMINESCENCEPhysics::Atomic and Molecular ClustersPhysics::Atomic PhysicsQuenchingOPTICAL GAINbusiness.industryCondensed Matter PhysicsElectronic Optical and Magnetic Materials1.54 MU-MchemistryOptoelectronicsQuantum efficiencySI NANOCRYSTALSENERGY-TRANSFERLuminescencebusinessPhysical Review B
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Photonic-crystal silicon-nanocluster light-emitting device

2006

We report on enhanced light extraction from a light-emitting device based on amorphous silicon nanoclusters, suitable for very-large-scale integration, and operating at room temperature. Standard low-cost optical lithography is employed to fabricate a two-dimensional photonic crystal onto the device. We measured a vertical emission with the extracted radiation enhanced by over a factor of 4, without the aid of any buried reflector. These achievements demonstrate that a cost-effective exploitation of photonic crystals is indeed within the reach of semiconductor industry and open the way to a new generation of nanostructured silicon devices in which photonic and electronic functions are integ…

Amorphous siliconMaterials sciencePhysics and Astronomy (miscellaneous)Siliconbusiness.industryHybrid silicon laserPhotonic integrated circuitchemistry.chemical_elementNanotechnologySettore ING-INF/01 - ElettronicaSettore FIS/03 - Fisica Della MateriaNanoclusterslaw.inventionchemistry.chemical_compoundNANOCRYSTALSchemistrylawELECTROLUMINESCENCEOptoelectronicslight-emitting devicePhotolithographyPhotonicsbusinessPhotonic crystal
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Electroluminescence and transport properties in amorphous silicon nanostructures

2006

We report the results of a detailed study on the structural, electrical and optical properties of light emitting devices based on amorphous Si nanostructures. Amorphous nanostructures may constitute an interesting system for the monolithic integration of optical and electrical functions in Si ULSI technology. In fact, they exhibit an intense room temperature electroluminescence (EL), with the advantage of being formed at a temperature of 900 °C, while at least 1100 °C is needed for the formation of Si nanocrystals. Optical and electrical properties of amorphous Si nanocluster devices have been studied in the temperature range between 30 and 300 K. The EL is seen to have a bell-shaped trend …

Amorphous siliconVISIBLE ELECTROLUMINESCENCEMaterials sciencePhysics and Astronomy (miscellaneous)nanostructures; silicon; elecroluminescenceExcitonBioengineeringElectronQUANTUM DOTSElectroluminescenceSettore ING-INF/01 - ElettronicaSettore FIS/03 - Fisica Della Materiachemistry.chemical_compoundnanostructuresGeneral Materials ScienceSI-RICH SIO2Electrical and Electronic EngineeringLIGHT-EMITTING DEVICESEngineering (miscellaneous)business.industryMechanical EngineeringsiliconGeneral ChemistryAtmospheric temperature rangeAmorphous solidCHEMICAL-VAPOR-DEPOSITIONelecroluminescenceNanocrystalchemistryMechanics of MaterialsOptoelectronicsMaterials Science (all)businessLuminescenceNanotechnology
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Photoluminescence transient study of surface defects in ZnO nanorods grown by chemical bath deposition

2015

Two deep level defects (2.25 and 2.03 eV) associated with oxygen vacancies (Vo) were identified in ZnO nanorods (NRs) grown by low cost chemical bath deposition. A transient behaviour in the photoluminescence (PL) intensity of the two Vo states was found to be sensitive to the ambient environment and to NR post-growth treatment. The largest transient was found in samples dried on a hot plate with a PL intensity decay time, in air only, of 23 and 80 s for the 2.25 and 2.03 eV peaks, respectively. Resistance measurements under UV exposure exhibited a transient behaviour in full agreement with the PL transient, indicating a clear role of atmospheric O-2 on the surface defect states. A model fo…

PhotoluminescencePhysics and Astronomy (miscellaneous)Analytical chemistryPhotovoltaic applicationFOS: Physical scienceschemistry.chemical_elementNanorodOxygen vacancieSettore ING-INF/01 - ElettronicaOxygensymbols.namesakeMesoscale and Nanoscale Physics (cond-mat.mes-hall)ultravioletSurface defect stateDepositionPhotoluminescenceChemical-bath depositionTransient studies Surface defectsPhysicsCondensed Matter - Mesoscale and Nanoscale PhysicsFermi levelDeep-level defectBand bendingnanowireschemistryZinc oxide Ambient environmentsymbolsNanorodPhotoluminescence intensitiefilmsTransient (oscillation)Resistance measurementIntensity (heat transfer)Chemical bath depositionApplied Physics Letters
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Light absorption in silicon quantum dots embedded in silica

2009

The photon absorption in Si quantum dots (QDs) embedded in SiO2 has been systematically investigated by varying several parameters of the QD synthesis. Plasma-enhanced chemical vapor deposition (PECVD) or magnetron cosputtering (MS) have been used to deposit, upon quartz substrates, single layer, or multilayer structures of Si-rich- SiO2 (SRO) with different Si content (43-46 at. %). SRO samples have been annealed for 1 h in the 450-1250 °C range and characterized by optical absorption measurements, photoluminescence analysis, Rutherford backscattering spectrometry and x-ray Photoelectron Spectroscopy. After annealing up to 900 °C SRO films grown by MS show a higher absorption coefficient a…

SOLAR-CELLSPhotoluminescenceMaterials scienceEFFICIENCYSiliconAnalytical chemistryGeneral Physics and Astronomychemistry.chemical_elementChemical vapor depositionOPTICAL-PROPERTIESRutherford backscattering spectrometryFILMSSettore ING-INF/01 - Elettronica3RD-GENERATION PHOTOVOLTAICSSettore FIS/03 - Fisica Della MateriaMULTIPLE EXCITON GENERATIONchemistryX-ray photoelectron spectroscopyPlasma-enhanced chemical vapor depositionQuantum dotRAY PHOTOELECTRON-SPECTROSCOPYLUMINESCENCESI NANOCRYSTALSCOEFFICIENTAbsorption (electromagnetic radiation)
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