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Optical Properties of Silicon Nanocrystallites Prepared by Excimer Laser Ablation in Inert Gas
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1996
Year
Excimer Laser AblationOptical MaterialsEngineeringLaser AblationLaser MaterialColloidal NanocrystalsChemistryExcitation Light IrradiationSilicon On InsulatorInert GasOptical PropertiesNanophotonicsMaterials SciencePhotoluminescencePhysicsNanotechnologyLaser Processing TechnologyOptical CeramicLaser-assisted DepositionNanocrystalline MaterialExcimer LasersNanomaterialsNatural SciencesApplied PhysicsParticle SizeOptoelectronics
Silicon nanocrystallites produced by excimer laser ablation in inert gas were investigated for size‑dependent optical properties. Red photoluminescence from oxidized Si nanocrystallites is size‑independent and photostable, whereas green photoluminescence is size‑dependent, degrades under air irradiation but recovers in vacuum, indicating a quantum‑confinement origin.
Optical properties of silicon (Si) nanocrystallites prepared by excimer laser ablation in constant-pressure inert gas have been studied in relation to the particle size. Visible photoluminescence (PL) bands in the red and green spectral regions appear at room temperature after an oxidation process. The red PL band is independent of the particle size and is stable without degradation by excitation light irradiation. It is concluded that the red PL is emitted from the surface states of the oxidized Si nanocrystallites. In contrast, the green PL band depends on the particle size. The green PL intensity decreases during excitation light irradiation in air, and then recovers in the subsequent vacuum evacuation. These results suggest that the origin of the green PL is associated with a quantum confinement effect of Si nanocrystallites.