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Numerical simulation of the effect of gold doping on the resistance to neutron irradiation of silicon diodes

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Numerical simulation of the effect of gold doping on the resistance to neutron irradiation of silicon diodes. / Bekhouche, K.; Sengouga, N.; Jones, Brian K.
In: Journal of Semiconductors, Vol. 36, No. 1, 14001, 2015.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Bekhouche, K, Sengouga, N & Jones, BK 2015, 'Numerical simulation of the effect of gold doping on the resistance to neutron irradiation of silicon diodes', Journal of Semiconductors, vol. 36, no. 1, 14001. https://doi.org/10.1088/1674-4926/36/1/014001

APA

Bekhouche, K., Sengouga, N., & Jones, B. K. (2015). Numerical simulation of the effect of gold doping on the resistance to neutron irradiation of silicon diodes. Journal of Semiconductors, 36(1), Article 14001. https://doi.org/10.1088/1674-4926/36/1/014001

Vancouver

Bekhouche K, Sengouga N, Jones BK. Numerical simulation of the effect of gold doping on the resistance to neutron irradiation of silicon diodes. Journal of Semiconductors. 2015;36(1):14001. doi: 10.1088/1674-4926/36/1/014001

Author

Bekhouche, K. ; Sengouga, N. ; Jones, Brian K. / Numerical simulation of the effect of gold doping on the resistance to neutron irradiation of silicon diodes. In: Journal of Semiconductors. 2015 ; Vol. 36, No. 1.

Bibtex

@article{93fa23271e7a42339822462041900896,
title = "Numerical simulation of the effect of gold doping on the resistance to neutron irradiation of silicon diodes",
abstract = "We have carried out a numerical simulation of the effect of gold doping on the electrical characteristics of long silicon diodes exposed to neutron irradiation. The aim is to investigate the effect of gold on the hardness of the irradiated diodes. The reverse current voltage and capacitance voltage characteristics of doped and undoped diodes are calculated for different irradiation doses. The leakage current and the effective doping density are extracted from these two characteristics respectively. The hardness of the diodes is evaluated from the evolution of the leakage current and the effective doping density with irradiation doses. It was found that diodes doped with gold are less sensitive to irradiation than undoped ones. Thus gold appears to stabilise the electrical properties on irradiation. The conduction mechanism is studied by the evolution of the current with temperature. The evaluated activation energy indicates that as the gold doping or irradiation dose increases, the current switches from the basic diffusion to the generation-recombination process, and that it can even become ohmic for very high gold densities or irradiation doses.",
keywords = "silicon diodes, gold doping, numerical simulation",
author = "K. Bekhouche and N. Sengouga and Jones, {Brian K.}",
year = "2015",
doi = "10.1088/1674-4926/36/1/014001",
language = "English",
volume = "36",
journal = "Journal of Semiconductors",
issn = "1674-4926",
publisher = "IOS Press",
number = "1",

}

RIS

TY - JOUR

T1 - Numerical simulation of the effect of gold doping on the resistance to neutron irradiation of silicon diodes

AU - Bekhouche, K.

AU - Sengouga, N.

AU - Jones, Brian K.

PY - 2015

Y1 - 2015

N2 - We have carried out a numerical simulation of the effect of gold doping on the electrical characteristics of long silicon diodes exposed to neutron irradiation. The aim is to investigate the effect of gold on the hardness of the irradiated diodes. The reverse current voltage and capacitance voltage characteristics of doped and undoped diodes are calculated for different irradiation doses. The leakage current and the effective doping density are extracted from these two characteristics respectively. The hardness of the diodes is evaluated from the evolution of the leakage current and the effective doping density with irradiation doses. It was found that diodes doped with gold are less sensitive to irradiation than undoped ones. Thus gold appears to stabilise the electrical properties on irradiation. The conduction mechanism is studied by the evolution of the current with temperature. The evaluated activation energy indicates that as the gold doping or irradiation dose increases, the current switches from the basic diffusion to the generation-recombination process, and that it can even become ohmic for very high gold densities or irradiation doses.

AB - We have carried out a numerical simulation of the effect of gold doping on the electrical characteristics of long silicon diodes exposed to neutron irradiation. The aim is to investigate the effect of gold on the hardness of the irradiated diodes. The reverse current voltage and capacitance voltage characteristics of doped and undoped diodes are calculated for different irradiation doses. The leakage current and the effective doping density are extracted from these two characteristics respectively. The hardness of the diodes is evaluated from the evolution of the leakage current and the effective doping density with irradiation doses. It was found that diodes doped with gold are less sensitive to irradiation than undoped ones. Thus gold appears to stabilise the electrical properties on irradiation. The conduction mechanism is studied by the evolution of the current with temperature. The evaluated activation energy indicates that as the gold doping or irradiation dose increases, the current switches from the basic diffusion to the generation-recombination process, and that it can even become ohmic for very high gold densities or irradiation doses.

KW - silicon diodes

KW - gold doping

KW - numerical simulation

U2 - 10.1088/1674-4926/36/1/014001

DO - 10.1088/1674-4926/36/1/014001

M3 - Journal article

VL - 36

JO - Journal of Semiconductors

JF - Journal of Semiconductors

SN - 1674-4926

IS - 1

M1 - 14001

ER -