Rita Magri scite author profile

Light-emitting silicon nanocrystals embedded in SiO 2 have been investigated by x-ray absorption measurements in total electron and photoluminescence yields, by energy filtered transmission electron microscopy and by ab initio total energy calculations. Both experimental and theoretical results show that the interface between the silicon nanocrystals and the surrounding SiO 2 is not sharp: an intermediate region of amorphous nature and variable composition links the crystalline Si with the amorphous stoichiometric SiO 2. This region plays an active role in the light-emission process.

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First-principles study ofn- andp-doped silicon nanoclusters

Cantele¹,

et al. 2005

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Ground-state structures and the random-state energy of the Madelung lattice

1990

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Engineering silicon nanocrystals: Theoretical study of the effect of codoping with boron and phosphorus

et al. 2007

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We show that the optical and electronic properties of nanocrystalline silicon can be efficiently tuned using impurity doping. In particular, we give evidence, by means of ab initio calculations, that by properly controlling the doping with either one or two atomic species, a significant modification of both the absorption and the emission of light can be achieved. We have considered impurities, either boron or phosphorous (doping) or both (codoping), located at different substitutional sites of silicon nanocrystals with size ranging from 1.1 to 1.8 nm in diameter. We have found that the codoped nanocrystals have the lowest impurity formation energies when the two impurities occupy nearest neighbor sites near the surface. In addition, such systems present band-edge states localized on the impurities, giving rise to a redshift of the absorption thresholds with respect to that of undoped nanocrystals. Our detailed theoretical analysis shows that the creation of an electron-hole pair due to light absorption determines a geometry distortion that, in turn, results in a Stokes shift between adsorption and emission spectra. In order to give a deeper insight into this effect, in one case we have calculated the absorption and emission spectra beyond the single-particle approach, showing the important role played by many-body effects. The entire set of results we have collected in this work give a strong indication that with the doping it is possible to tune the optical properties of silicon nanocrystals

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Rita Magri

Role of the interface region on the optoelectronic properties of silicon nanocrystals embedded inSiO2

First-principles study ofn- andp-doped silicon nanoclusters

Ground-state structures and the random-state energy of the Madelung lattice

Engineering silicon nanocrystals: Theoretical study of the effect of codoping with boron and phosphorus

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