Doped semiconductor nanocrystal junctions

Borowik; T. Nguyen-Tran; P. Roca I Cabarrocas; T. Mélin

doi:10.1063/1.4834516

Doped semiconductor nanocrystal junctions

Borowik
, T. Nguyen-Tran
, P. Roca I Cabarrocas
, T. Mélin

Institut d'Electronique de Microélectronique et de Nanotechnologie (IEMN)
Institut polytechnique de Paris

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

Semiconductor junctions are the basis of electronic and photovoltaic devices. Here, we investigate junctions formed from highly doped (N D ≈ 10 20 - 10 21cm^-3) silicon nanocrystals (NCs) in the 2-50 nm size range, using Kelvin probe force microscopy experiments with single charge sensitivity. We show that the charge transfer from doped NCs towards a two-dimensional layer experimentally follows a simple phenomenological law, corresponding to formation of an interface dipole linearly increasing with the NC diameter. This feature leads to analytically predictable junction properties down to quantum size regimes: NC depletion width independent of the NC size and varying as N D - 1 / 3, and depleted charge linearly increasing with the NC diameter and varying as N D 1 / 3. We thus establish a "nanocrystal counterpart" of conventional semiconductor planar junctions, here however valid in regimes of strong electrostatic and quantum confinements.

langue originale	Anglais
Numéro d'article	204305
journal	Journal of Applied Physics
Volume	114
Numéro de publication	20
Les DOIs	https://doi.org/10.1063/1.4834516
état	Publié - 28 nov. 2013

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title = "Doped semiconductor nanocrystal junctions",

abstract = "Semiconductor junctions are the basis of electronic and photovoltaic devices. Here, we investigate junctions formed from highly doped (N D ≈ 10 20 - 10 21cm-3) silicon nanocrystals (NCs) in the 2-50 nm size range, using Kelvin probe force microscopy experiments with single charge sensitivity. We show that the charge transfer from doped NCs towards a two-dimensional layer experimentally follows a simple phenomenological law, corresponding to formation of an interface dipole linearly increasing with the NC diameter. This feature leads to analytically predictable junction properties down to quantum size regimes: NC depletion width independent of the NC size and varying as N D - 1 / 3, and depleted charge linearly increasing with the NC diameter and varying as N D 1 / 3. We thus establish a {"}nanocrystal counterpart{"} of conventional semiconductor planar junctions, here however valid in regimes of strong electrostatic and quantum confinements.",

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AU - Mélin, T.

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N2 - Semiconductor junctions are the basis of electronic and photovoltaic devices. Here, we investigate junctions formed from highly doped (N D ≈ 10 20 - 10 21cm-3) silicon nanocrystals (NCs) in the 2-50 nm size range, using Kelvin probe force microscopy experiments with single charge sensitivity. We show that the charge transfer from doped NCs towards a two-dimensional layer experimentally follows a simple phenomenological law, corresponding to formation of an interface dipole linearly increasing with the NC diameter. This feature leads to analytically predictable junction properties down to quantum size regimes: NC depletion width independent of the NC size and varying as N D - 1 / 3, and depleted charge linearly increasing with the NC diameter and varying as N D 1 / 3. We thus establish a "nanocrystal counterpart" of conventional semiconductor planar junctions, here however valid in regimes of strong electrostatic and quantum confinements.

AB - Semiconductor junctions are the basis of electronic and photovoltaic devices. Here, we investigate junctions formed from highly doped (N D ≈ 10 20 - 10 21cm-3) silicon nanocrystals (NCs) in the 2-50 nm size range, using Kelvin probe force microscopy experiments with single charge sensitivity. We show that the charge transfer from doped NCs towards a two-dimensional layer experimentally follows a simple phenomenological law, corresponding to formation of an interface dipole linearly increasing with the NC diameter. This feature leads to analytically predictable junction properties down to quantum size regimes: NC depletion width independent of the NC size and varying as N D - 1 / 3, and depleted charge linearly increasing with the NC diameter and varying as N D 1 / 3. We thus establish a "nanocrystal counterpart" of conventional semiconductor planar junctions, here however valid in regimes of strong electrostatic and quantum confinements.

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Doped semiconductor nanocrystal junctions

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