Doping efficiency in freestanding silicon nanocrystals from the gas phase: Phosphorus incorporation and defect-induced compensation

A. R. Stegner; R. N. Pereira; R. Lechner; K. Klein; H. Wiggers; M. Stutzmann; M. S. Brandt

doi:10.1103/PhysRevB.80.165326

Doping efficiency in freestanding silicon nanocrystals from the gas phase: Phosphorus incorporation and defect-induced compensation

A. R. Stegner, R. N. Pereira, R. Lechner, K. Klein, H. Wiggers, M. Stutzmann, M. S. Brandt

TUM Emeriti of Excellence

Research output: Contribution to journal › Article › peer-review

110 Scopus citations

Abstract

Electron paramagnetic resonance (EPR) and secondary-ion mass spectroscopy have been used to quantitatively investigate the phosphorus doping of freestanding silicon nanocrystals (Si-NCs) in a wide range of diameters. It is found that both the atomic phosphorus incorporation efficiency of 100% and its segregation to the surface region during growth by our gas-phase method are independent of the nominal doping concentration and the Si-NC size. EPR data show that the concentration of electrically active substitutional P falls below the atomic P concentration by about 1 order of magnitude for Si-NC with diameters larger than 12 nm. Using a quantitative statistical model, charge compensation by Si dangling bonds is shown to be the reason for this difference. For smaller Si-NCs, a further strong drop of the concentration of paramagnetic donors is observed.

Original language	English
Article number	165326
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	80
Issue number	16
DOIs	https://doi.org/10.1103/PhysRevB.80.165326
State	Published - 23 Oct 2009

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abstract = "Electron paramagnetic resonance (EPR) and secondary-ion mass spectroscopy have been used to quantitatively investigate the phosphorus doping of freestanding silicon nanocrystals (Si-NCs) in a wide range of diameters. It is found that both the atomic phosphorus incorporation efficiency of 100% and its segregation to the surface region during growth by our gas-phase method are independent of the nominal doping concentration and the Si-NC size. EPR data show that the concentration of electrically active substitutional P falls below the atomic P concentration by about 1 order of magnitude for Si-NC with diameters larger than 12 nm. Using a quantitative statistical model, charge compensation by Si dangling bonds is shown to be the reason for this difference. For smaller Si-NCs, a further strong drop of the concentration of paramagnetic donors is observed.",

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T2 - Phosphorus incorporation and defect-induced compensation

AU - Stegner, A. R.

AU - Pereira, R. N.

AU - Lechner, R.

AU - Klein, K.

AU - Wiggers, H.

AU - Stutzmann, M.

AU - Brandt, M. S.

PY - 2009/10/23

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N2 - Electron paramagnetic resonance (EPR) and secondary-ion mass spectroscopy have been used to quantitatively investigate the phosphorus doping of freestanding silicon nanocrystals (Si-NCs) in a wide range of diameters. It is found that both the atomic phosphorus incorporation efficiency of 100% and its segregation to the surface region during growth by our gas-phase method are independent of the nominal doping concentration and the Si-NC size. EPR data show that the concentration of electrically active substitutional P falls below the atomic P concentration by about 1 order of magnitude for Si-NC with diameters larger than 12 nm. Using a quantitative statistical model, charge compensation by Si dangling bonds is shown to be the reason for this difference. For smaller Si-NCs, a further strong drop of the concentration of paramagnetic donors is observed.

AB - Electron paramagnetic resonance (EPR) and secondary-ion mass spectroscopy have been used to quantitatively investigate the phosphorus doping of freestanding silicon nanocrystals (Si-NCs) in a wide range of diameters. It is found that both the atomic phosphorus incorporation efficiency of 100% and its segregation to the surface region during growth by our gas-phase method are independent of the nominal doping concentration and the Si-NC size. EPR data show that the concentration of electrically active substitutional P falls below the atomic P concentration by about 1 order of magnitude for Si-NC with diameters larger than 12 nm. Using a quantitative statistical model, charge compensation by Si dangling bonds is shown to be the reason for this difference. For smaller Si-NCs, a further strong drop of the concentration of paramagnetic donors is observed.

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Doping efficiency in freestanding silicon nanocrystals from the gas phase: Phosphorus incorporation and defect-induced compensation

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