Toward understanding and optimizing Au-hyperdoped Si infrared photodetectors

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

doi:10.1063/5.0010083

Toward understanding and optimizing Au-hyperdoped Si infrared photodetectors

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

^*Corresponding author for this work

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

22 Citations (Scopus)

Abstract

Au-hyperdoped Si absorbs near-infrared (NIR) light and recent efforts have successfully produced Si-based NIR photodetectors based on this property but with low detection efficiencies. Here, we investigate the differences between the optical and photocurrent properties of Au-hyperdoped Si. Although defects introduced during fabrication of these materials may not exhibit significant optical absorption, we show that they can produce a measurable photocurrent under NIR illumination. Our results indicate that the optimal efficiency of impurity-hyperdoped Si materials is yet to be achieved and we discuss these opportunities in light of our results. This work thus represents a step forward in demonstrating the viability of using impurity-hyperdoped Si materials for NIR photodetection.

Original language	English
Article number	061109
Journal	APL Materials
Volume	8
Issue number	6
DOIs	https://doi.org/10.1063/5.0010083
Publication status	Published - 1 Jun 2020

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title = "Toward understanding and optimizing Au-hyperdoped Si infrared photodetectors",

abstract = "Au-hyperdoped Si absorbs near-infrared (NIR) light and recent efforts have successfully produced Si-based NIR photodetectors based on this property but with low detection efficiencies. Here, we investigate the differences between the optical and photocurrent properties of Au-hyperdoped Si. Although defects introduced during fabrication of these materials may not exhibit significant optical absorption, we show that they can produce a measurable photocurrent under NIR illumination. Our results indicate that the optimal efficiency of impurity-hyperdoped Si materials is yet to be achieved and we discuss these opportunities in light of our results. This work thus represents a step forward in demonstrating the viability of using impurity-hyperdoped Si materials for NIR photodetection.",

author = "Lim, {S. Q.} and Lew, {C. T.K.} and Chow, {P. K.} and Warrender, {J. M.} and Williams, {J. S.} and Johnson, {B. C.}",

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AU - Lim, S. Q.

AU - Lew, C. T.K.

AU - Chow, P. K.

AU - Warrender, J. M.

AU - Williams, J. S.

AU - Johnson, B. C.

PY - 2020/6/1

Y1 - 2020/6/1

N2 - Au-hyperdoped Si absorbs near-infrared (NIR) light and recent efforts have successfully produced Si-based NIR photodetectors based on this property but with low detection efficiencies. Here, we investigate the differences between the optical and photocurrent properties of Au-hyperdoped Si. Although defects introduced during fabrication of these materials may not exhibit significant optical absorption, we show that they can produce a measurable photocurrent under NIR illumination. Our results indicate that the optimal efficiency of impurity-hyperdoped Si materials is yet to be achieved and we discuss these opportunities in light of our results. This work thus represents a step forward in demonstrating the viability of using impurity-hyperdoped Si materials for NIR photodetection.

AB - Au-hyperdoped Si absorbs near-infrared (NIR) light and recent efforts have successfully produced Si-based NIR photodetectors based on this property but with low detection efficiencies. Here, we investigate the differences between the optical and photocurrent properties of Au-hyperdoped Si. Although defects introduced during fabrication of these materials may not exhibit significant optical absorption, we show that they can produce a measurable photocurrent under NIR illumination. Our results indicate that the optimal efficiency of impurity-hyperdoped Si materials is yet to be achieved and we discuss these opportunities in light of our results. This work thus represents a step forward in demonstrating the viability of using impurity-hyperdoped Si materials for NIR photodetection.

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VL - 8

JO - APL Materials

JF - APL Materials

IS - 6

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Toward understanding and optimizing Au-hyperdoped Si infrared photodetectors

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