Ge1-y Sny photoconductor structures at 1.55 μm: From advanced materials to prototype devices

R. Roucka; J. Xie; John Kouvetakis; J. Mathews; V. D'Costa; Jose Menendez; J. Tolle; S. Q. Yu

doi:10.1116/1.3021024

Ge1-y Sny photoconductor structures at 1.55 μm: From advanced materials to prototype devices

R. Roucka, J. Xie, John Kouvetakis, J. Mathews, V. D'Costa, Jose Menendez, J. Tolle, S. Q. Yu

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

39 Scopus citations

Abstract

Prototype detector structures were fabricated on Si substrates using Ge1-y Sny as active material for the first time. This alloy system covers the entire near-IR telecommunication spectrum and grows at a low temperature of 350 °C, compatible with complementary metal-oxide-semiconductor (CMOS) Si technology. Processing protocols were developed for photolithography-based patterning and subsequent etching, CMOS compatible metallization, and for the formation of low-resistivity Ohmic contacts. A first generation of devices based on as-grown Ge1-y Sny layers was followed by a second generation incorporating ex situ rapid thermal annealing for defect reduction, as well as additional growth and processing improvements, leading to enhanced mobilities and simultaneous reduction in intrinsic carrier concentrations. While both device generations show a significant photoconductive response at 1.55 μm, the thicker second-generation samples yield improved performance due to better confinement of deleterious defects near the interface, which increases the optically active fraction of the film.

Original language	English (US)
Pages (from-to)	1952-1959
Number of pages	8
Journal	Journal of Vacuum Science and Technology B: Microelectronics and Nanometer Structures
Volume	26
Issue number	6
DOIs	https://doi.org/10.1116/1.3021024
State	Published - 2008

ASJC Scopus subject areas

Condensed Matter Physics
Electrical and Electronic Engineering

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title = "Ge1-y Sny photoconductor structures at 1.55 μm: From advanced materials to prototype devices",

abstract = "Prototype detector structures were fabricated on Si substrates using Ge1-y Sny as active material for the first time. This alloy system covers the entire near-IR telecommunication spectrum and grows at a low temperature of 350 °C, compatible with complementary metal-oxide-semiconductor (CMOS) Si technology. Processing protocols were developed for photolithography-based patterning and subsequent etching, CMOS compatible metallization, and for the formation of low-resistivity Ohmic contacts. A first generation of devices based on as-grown Ge1-y Sny layers was followed by a second generation incorporating ex situ rapid thermal annealing for defect reduction, as well as additional growth and processing improvements, leading to enhanced mobilities and simultaneous reduction in intrinsic carrier concentrations. While both device generations show a significant photoconductive response at 1.55 μm, the thicker second-generation samples yield improved performance due to better confinement of deleterious defects near the interface, which increases the optically active fraction of the film.",

author = "R. Roucka and J. Xie and John Kouvetakis and J. Mathews and V. D'Costa and Jose Menendez and J. Tolle and Yu, {S. Q.}",

note = "Funding Information: This work was supported by AFOSR MURI (Grant No. FA9550-06-01-0442) and the National Science Foundation (Grant No. IIP-0638253). This work was also supported by the optical interconnect project of the IFC group managed by Georgia Tech/Stanford Universities.",

year = "2008",

doi = "10.1116/1.3021024",

language = "English (US)",

volume = "26",

pages = "1952--1959",

journal = "Journal of Vacuum Science and Technology B: Microelectronics and Nanometer Structures",

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T2 - From advanced materials to prototype devices

AU - Roucka, R.

AU - Xie, J.

AU - Kouvetakis, John

AU - Mathews, J.

AU - D'Costa, V.

AU - Menendez, Jose

AU - Tolle, J.

AU - Yu, S. Q.

N1 - Funding Information: This work was supported by AFOSR MURI (Grant No. FA9550-06-01-0442) and the National Science Foundation (Grant No. IIP-0638253). This work was also supported by the optical interconnect project of the IFC group managed by Georgia Tech/Stanford Universities.

PY - 2008

Y1 - 2008

N2 - Prototype detector structures were fabricated on Si substrates using Ge1-y Sny as active material for the first time. This alloy system covers the entire near-IR telecommunication spectrum and grows at a low temperature of 350 °C, compatible with complementary metal-oxide-semiconductor (CMOS) Si technology. Processing protocols were developed for photolithography-based patterning and subsequent etching, CMOS compatible metallization, and for the formation of low-resistivity Ohmic contacts. A first generation of devices based on as-grown Ge1-y Sny layers was followed by a second generation incorporating ex situ rapid thermal annealing for defect reduction, as well as additional growth and processing improvements, leading to enhanced mobilities and simultaneous reduction in intrinsic carrier concentrations. While both device generations show a significant photoconductive response at 1.55 μm, the thicker second-generation samples yield improved performance due to better confinement of deleterious defects near the interface, which increases the optically active fraction of the film.

AB - Prototype detector structures were fabricated on Si substrates using Ge1-y Sny as active material for the first time. This alloy system covers the entire near-IR telecommunication spectrum and grows at a low temperature of 350 °C, compatible with complementary metal-oxide-semiconductor (CMOS) Si technology. Processing protocols were developed for photolithography-based patterning and subsequent etching, CMOS compatible metallization, and for the formation of low-resistivity Ohmic contacts. A first generation of devices based on as-grown Ge1-y Sny layers was followed by a second generation incorporating ex situ rapid thermal annealing for defect reduction, as well as additional growth and processing improvements, leading to enhanced mobilities and simultaneous reduction in intrinsic carrier concentrations. While both device generations show a significant photoconductive response at 1.55 μm, the thicker second-generation samples yield improved performance due to better confinement of deleterious defects near the interface, which increases the optically active fraction of the film.

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Ge1-y Sny photoconductor structures at 1.55 μm: From advanced materials to prototype devices

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