Silicon nitride engineering: Role of hydrogen-bonding in Ge quantum dot formation

Kan Ping Peng; Yu Hong Kuo; Li Hsin Chang; Chien Nan Hsiao; Tsai Fu Chung; Thomas George; Horng Chin Lin; Pei Wen Li

doi:10.1088/1361-6641/abaa2a

Silicon nitride engineering: Role of hydrogen-bonding in Ge quantum dot formation

Kan Ping Peng, Yu Hong Kuo, Li Hsin Chang, Chien Nan Hsiao, Tsai Fu Chung, Thomas George, Horng Chin Lin, Pei Wen Li^*

^*Corresponding author for this work

Institute of Electronics

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

4 Scopus citations

Abstract

We report the lowering of the formation temperature of spherical-shaped Ge quantum dots (QDs) to 850 ^◦C from our previously-reported 900 ^◦C. This large reduction in QD formation temperature was achieved via the use of a hydrogenated, plasma-enhanced chemical-vapor deposited (PECVD) silicon nitride (SiN). The exquisite interplay between H, Ge, Si and O interstitials, controlling QD formation during the thermal oxidation of poly-SiGe layers deposited over PECVD-Si_xN_y: H, is further explored in order to understand the underlying mechanisms. We have experimentally observed that the high hydrogen content of the PECVD-Si_xN_y: H facilitates the lower-temperature (850 ^◦C) oxidation of the nitride layer, while simultaneously being able to generate smaller diameter, fully coalesced Ge QDs within. Such heterostructures of SiN coupled-Ge QDs are a fundamental building block for the ultimate fabrication of active SiN-based Ge photonic devices.

Original language	English
Article number	105018
Number of pages	9
Journal	Semiconductor Science and Technology
Volume	35
Issue number	10
DOIs	https://doi.org/10.1088/1361-6641/abaa2a
State	Published - Oct 2020

Keywords

Germanium
Hydrogen
Quantum dot
SiN

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title = "Silicon nitride engineering: Role of hydrogen-bonding in Ge quantum dot formation",

abstract = "We report the lowering of the formation temperature of spherical-shaped Ge quantum dots (QDs) to 850 ◦C from our previously-reported 900 ◦C. This large reduction in QD formation temperature was achieved via the use of a hydrogenated, plasma-enhanced chemical-vapor deposited (PECVD) silicon nitride (SiN). The exquisite interplay between H, Ge, Si and O interstitials, controlling QD formation during the thermal oxidation of poly-SiGe layers deposited over PECVD-SixNy: H, is further explored in order to understand the underlying mechanisms. We have experimentally observed that the high hydrogen content of the PECVD-SixNy: H facilitates the lower-temperature (850 ◦C) oxidation of the nitride layer, while simultaneously being able to generate smaller diameter, fully coalesced Ge QDs within. Such heterostructures of SiN coupled-Ge QDs are a fundamental building block for the ultimate fabrication of active SiN-based Ge photonic devices.",

keywords = "Germanium, Hydrogen, Quantum dot, SiN",

author = "Peng, {Kan Ping} and Kuo, {Yu Hong} and Chang, {Li Hsin} and Hsiao, {Chien Nan} and Chung, {Tsai Fu} and Thomas George and Lin, {Horng Chin} and Li, {Pei Wen}",

year = "2020",

month = oct,

doi = "10.1088/1361-6641/abaa2a",

language = "English",

volume = "35",

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TY - JOUR

T1 - Silicon nitride engineering

T2 - Role of hydrogen-bonding in Ge quantum dot formation

AU - Peng, Kan Ping

AU - Kuo, Yu Hong

AU - Chang, Li Hsin

AU - Hsiao, Chien Nan

AU - Chung, Tsai Fu

AU - George, Thomas

AU - Lin, Horng Chin

AU - Li, Pei Wen

PY - 2020/10

Y1 - 2020/10

N2 - We report the lowering of the formation temperature of spherical-shaped Ge quantum dots (QDs) to 850 ◦C from our previously-reported 900 ◦C. This large reduction in QD formation temperature was achieved via the use of a hydrogenated, plasma-enhanced chemical-vapor deposited (PECVD) silicon nitride (SiN). The exquisite interplay between H, Ge, Si and O interstitials, controlling QD formation during the thermal oxidation of poly-SiGe layers deposited over PECVD-SixNy: H, is further explored in order to understand the underlying mechanisms. We have experimentally observed that the high hydrogen content of the PECVD-SixNy: H facilitates the lower-temperature (850 ◦C) oxidation of the nitride layer, while simultaneously being able to generate smaller diameter, fully coalesced Ge QDs within. Such heterostructures of SiN coupled-Ge QDs are a fundamental building block for the ultimate fabrication of active SiN-based Ge photonic devices.

AB - We report the lowering of the formation temperature of spherical-shaped Ge quantum dots (QDs) to 850 ◦C from our previously-reported 900 ◦C. This large reduction in QD formation temperature was achieved via the use of a hydrogenated, plasma-enhanced chemical-vapor deposited (PECVD) silicon nitride (SiN). The exquisite interplay between H, Ge, Si and O interstitials, controlling QD formation during the thermal oxidation of poly-SiGe layers deposited over PECVD-SixNy: H, is further explored in order to understand the underlying mechanisms. We have experimentally observed that the high hydrogen content of the PECVD-SixNy: H facilitates the lower-temperature (850 ◦C) oxidation of the nitride layer, while simultaneously being able to generate smaller diameter, fully coalesced Ge QDs within. Such heterostructures of SiN coupled-Ge QDs are a fundamental building block for the ultimate fabrication of active SiN-based Ge photonic devices.

KW - Germanium

KW - Hydrogen

KW - Quantum dot

KW - SiN

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U2 - 10.1088/1361-6641/abaa2a

DO - 10.1088/1361-6641/abaa2a

M3 - Article

SN - 0268-1242

VL - 35

JO - Semiconductor Science and Technology

JF - Semiconductor Science and Technology

IS - 10

M1 - 105018

ER -

Silicon nitride engineering: Role of hydrogen-bonding in Ge quantum dot formation

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Keywords

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