Electronic transport in doped amorphous silicon

J. Kakalios; R. A. Street

doi:10.1103/PhysRevB.34.6014

Electronic transport in doped amorphous silicon

J. Kakalios, R. A. Street

Physics and Astronomy (Twin Cities)

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

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Abstract

The temperature dependence of the dc dark conductivity of doped hydrogenated amorphous silicon is explained by the defect-compensation model of doping with the proposal that the structure is in metastable thermal equilibrium. Observed conductivity activation energies and preexponential factors can be accounted for quantitatively. When the localized state distribution is in thermal equilibrium, the conductivity preexponential factor is the Mott minimum metallic conductivity.

Original language	English (US)
Pages (from-to)	6014-6017
Number of pages	4
Journal	Physical Review B
Volume	34
Issue number	8
DOIs	https://doi.org/10.1103/PhysRevB.34.6014
State	Published - 1986

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title = "Electronic transport in doped amorphous silicon",

abstract = "The temperature dependence of the dc dark conductivity of doped hydrogenated amorphous silicon is explained by the defect-compensation model of doping with the proposal that the structure is in metastable thermal equilibrium. Observed conductivity activation energies and preexponential factors can be accounted for quantitatively. When the localized state distribution is in thermal equilibrium, the conductivity preexponential factor is the Mott minimum metallic conductivity.",

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PY - 1986

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AB - The temperature dependence of the dc dark conductivity of doped hydrogenated amorphous silicon is explained by the defect-compensation model of doping with the proposal that the structure is in metastable thermal equilibrium. Observed conductivity activation energies and preexponential factors can be accounted for quantitatively. When the localized state distribution is in thermal equilibrium, the conductivity preexponential factor is the Mott minimum metallic conductivity.

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DO - 10.1103/PhysRevB.34.6014

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Electronic transport in doped amorphous silicon

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