Process-induced defects in Au-hyperdoped Si photodiodes

S. Q. Lim; C. T.K. Lew; P. K. Chow; J. M. Warrender; J. S. Williams; B. C. Johnson

doi:10.1063/1.5128146

Process-induced defects in Au-hyperdoped Si photodiodes

S. Q. Lim, C. T.K. Lew, P. K. Chow, J. M. Warrender, J. S. Williams, B. C. Johnson

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

18 Citations (Scopus)

Abstract

Hyperdoped Si formed by implantation followed by pulsed laser melting is a promising material for enhanced near-infrared photodetection. To realize the full potential of this material, it is crucial to understand the nature of defects arising from the fabrication process and how these may impact device operation. Here, we identify through deep level transient spectroscopy the presence of a range of defects in the substrate depletion layer that arise from interactions between high dose ion implantation and pulsed laser melting, and investigate their annealing behavior up to 650 °C. In particular, the detection of a vacancy complex E 1 (0.35) with densities as high as 10 14 cm - 3 indicates that optical transitions between this level and the valence band may compete with the Au donor center, and hence could potentially contribute to the photocurrent in hyperdoped photodiodes.

Original language	English
Article number	224502
Journal	Journal of Applied Physics
Volume	126
Issue number	22
DOIs	https://doi.org/10.1063/1.5128146
Publication status	Published - 14 Dec 2019

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abstract = "Hyperdoped Si formed by implantation followed by pulsed laser melting is a promising material for enhanced near-infrared photodetection. To realize the full potential of this material, it is crucial to understand the nature of defects arising from the fabrication process and how these may impact device operation. Here, we identify through deep level transient spectroscopy the presence of a range of defects in the substrate depletion layer that arise from interactions between high dose ion implantation and pulsed laser melting, and investigate their annealing behavior up to 650 °C. In particular, the detection of a vacancy complex E 1 (0.35) with densities as high as 10 14 cm - 3 indicates that optical transitions between this level and the valence band may compete with the Au donor center, and hence could potentially contribute to the photocurrent in hyperdoped photodiodes.",

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AU - Lim, S. Q.

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AU - Williams, J. S.

AU - Johnson, B. C.

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N2 - Hyperdoped Si formed by implantation followed by pulsed laser melting is a promising material for enhanced near-infrared photodetection. To realize the full potential of this material, it is crucial to understand the nature of defects arising from the fabrication process and how these may impact device operation. Here, we identify through deep level transient spectroscopy the presence of a range of defects in the substrate depletion layer that arise from interactions between high dose ion implantation and pulsed laser melting, and investigate their annealing behavior up to 650 °C. In particular, the detection of a vacancy complex E 1 (0.35) with densities as high as 10 14 cm - 3 indicates that optical transitions between this level and the valence band may compete with the Au donor center, and hence could potentially contribute to the photocurrent in hyperdoped photodiodes.

AB - Hyperdoped Si formed by implantation followed by pulsed laser melting is a promising material for enhanced near-infrared photodetection. To realize the full potential of this material, it is crucial to understand the nature of defects arising from the fabrication process and how these may impact device operation. Here, we identify through deep level transient spectroscopy the presence of a range of defects in the substrate depletion layer that arise from interactions between high dose ion implantation and pulsed laser melting, and investigate their annealing behavior up to 650 °C. In particular, the detection of a vacancy complex E 1 (0.35) with densities as high as 10 14 cm - 3 indicates that optical transitions between this level and the valence band may compete with the Au donor center, and hence could potentially contribute to the photocurrent in hyperdoped photodiodes.

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Process-induced defects in Au-hyperdoped Si photodiodes

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