Correlation between Optical Properties and Crystallite Size in Porous Silicon

Lehmann, Volker; Jobst, B.; Muschik, T.; Kux, A.; Petrova‐Koch, V.

doi:10.1143/jjap.32.2095

Cited by 101 publications

(45 citation statements)

References 5 publications

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“…Nevertheless, it is generally accepted that the PL emission is a consequence of a widening in the band gap due to quantum confinement in the nanocrystals [5]. Several studies confirm the presence of nanocrystals (called "quantum dots", QD) or aggregates of nanocrystals in long structures ("quantum wires", QW) in luminescent specimens [6][7][8][9][10][11][12]. The evidence points at the existence of statistical distributions of nanocrystal sizes mainly because the process of production of the specimens is highly stochastic [13][14][15][16][17].…”

Section: Introductionmentioning

confidence: 99%

Estimation of Silicon Nanocrystalline Sizes from Photoluminescence Measurements of RF Co-Sputtered Si/SiO₂ Films.

2002

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A stochastic distribution of nanocrystalline sizes model is applied to fit photoluminescence (PL) spectra of luminescent Si nanocrystals in a Si/SiO 2 matrix synthesized by RF co-sputtering on the top of quartz substrates. With this method, the PL spectra from a diverse set of samples can be resolved mainly as the sum of two components: a contribution from a gaussian-like distribution of sizes of quantum dots (QD) and a similar component from a distribution of quantum wires (QW). These distributions of sizes and their associated PL energies agree well with the so-called Smart Quantum Confinement model (SQC).

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Section: Introductionmentioning

confidence: 99%

Estimation of Silicon Nanocrystalline Sizes from Photoluminescence Measurements of RF Co-Sputtered Si/SiO₂ Films.

2002

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“…Estimated thickness of the basic layer was about six times the thickness of the auxiliary layer. Calculations of geometry and porosity of the layers were based on data depending on density of the dc current and duration of etching [14,15]. Contacts were made by vacuum evaporation of aluminium and subsequent annealing at temperature of 450 • C in nitrogen atmosphere.…”

Section: Methodsmentioning

confidence: 99%

Effect of microwave radiation on conductivity of porous silicon nanostructures

Shatkovskis¹

2007

Lithuanian J. Phys.

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An attempt was made to find out the possible influence of microwave radiation on the conductivity of structures containing porous silicon layers. Samples have been made of boron doped p-type, (100) oriented, ρ = 0.4 Ω·cm specific resistance silicon wafers by technology involving electrochemical etching in HF : ethanol = 1 : 2 electrolyte, and subsequent preparation of contacts. Two kinds of prepared samples have been characterized by nonlinear and linear current-voltage characteristics. Electric conductivity of the samples was investigated under the action of 10 GHz frequency microwave radiation. Activation nature of porous silicon conductivity was revealed. Model of hopping conductivity in the vicinity of Fermi level in the lattice of a porous silicon grid, considering the fractal character of porous silicon skeleton, has been applied to explain experimental results. Three activation energies were found: E 0 , E 0 , and E 0 (E 0 < E 0 < E 0 ), caused by fractal character of a porous silicon grid. Activation of conductivity occurs because of charge carrier heating in porous silicon structure by microwave radiation.

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“…Direct evidence for stress induced silicon wafer bending during voltage oscillations of the Si/HF system was presented by Lehman [22]. Finally, investigations with Highresolution X-ray diffraction proved the existence of stress forces across porous silicon layers [23]. The finding has been attributed to the specific termination of the pore walls by Si-H x leading predominantly to vertical strain [24,25].…”

Section: Model Considerationsmentioning

confidence: 98%

Scaling effects upon fractal etch pattern formation on silicon photoelectrodes

Lublow

Lewerenz

2009

Electrochimica Acta

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Correlation between Optical Properties and Crystallite Size in Porous Silicon

Cited by 101 publications

References 5 publications

Estimation of Silicon Nanocrystalline Sizes from Photoluminescence Measurements of RF Co-Sputtered Si/SiO₂ Films.

Estimation of Silicon Nanocrystalline Sizes from Photoluminescence Measurements of RF Co-Sputtered Si/SiO₂ Films.

Effect of microwave radiation on conductivity of porous silicon nanostructures

Scaling effects upon fractal etch pattern formation on silicon photoelectrodes

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Correlation between Optical Properties and Crystallite Size in Porous Silicon

Cited by 101 publications

References 5 publications

Estimation of Silicon Nanocrystalline Sizes from Photoluminescence Measurements of RF Co-Sputtered Si/SiO2 Films.

Estimation of Silicon Nanocrystalline Sizes from Photoluminescence Measurements of RF Co-Sputtered Si/SiO2 Films.

Effect of microwave radiation on conductivity of porous silicon nanostructures

Scaling effects upon fractal etch pattern formation on silicon photoelectrodes

Contact Info

Product

Resources

About

Estimation of Silicon Nanocrystalline Sizes from Photoluminescence Measurements of RF Co-Sputtered Si/SiO₂ Films.

Estimation of Silicon Nanocrystalline Sizes from Photoluminescence Measurements of RF Co-Sputtered Si/SiO₂ Films.