Optical properties of nitride-rich SiNx and its use in CMOS-compatible near-UV Bragg filter fabrication

Reinoud F. Wolffenbuttel; Declan Winship; Yutao Qin; Yogesh Gianchandani; David Bilby; Jaco H. Visser

doi:10.1016/j.omx.2024.100348

Optical properties of nitride-rich SiN_x and its use in CMOS-compatible near-UV Bragg filter fabrication

Reinoud F. Wolffenbuttel^*, Declan Winship, Yutao Qin, Yogesh Gianchandani, David Bilby, Jaco H. Visser

^*Corresponding author for this work

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Abstract

Nitride-rich silicon-nitride (SiNx) is being explored for its potential as a suitable optical material for use in microsystems operating in the near-UV spectral range. Although silicon-rich SiNx is widely accepted as a CMOS-compatible dielectric and micromechanical material, its optical absorption limits application to the visible to near-IR spectral range. However, this work shows that a balance can be achieved between a sufficiently high index of refraction (n> 2) and an acceptable optical loss (k<10−3) in nitride-rich SiNx of appropriate composition (x∼1.45). Bragg reflectors with a design wavelength at λo= 330 nm are used for validation. PECVD is used for sample preparation and experiments confirm that the spectral range available for use of SiNx-based optical microsystems extends to wavelengths as low as 300 nm.

Original language	English
Article number	100348
Number of pages	9
Journal	Optical Materials: X
Volume	24
DOIs	https://doi.org/10.1016/j.omx.2024.100348
Publication status	Published - 2024

Keywords

CMOS compatibility
Integrated silicon optical microsystems
Near-UV optical filter
Optical MEMS technology
Silicon-nitride

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10.1016/j.omx.2024.100348

1-s2.0-S2590147824000603-mainFinal published version, 3.2 MBLicence: CC BY-NC

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title = "Optical properties of nitride-rich SiNx and its use in CMOS-compatible near-UV Bragg filter fabrication",

abstract = "Nitride-rich silicon-nitride (SiNx) is being explored for its potential as a suitable optical material for use in microsystems operating in the near-UV spectral range. Although silicon-rich SiNx is widely accepted as a CMOS-compatible dielectric and micromechanical material, its optical absorption limits application to the visible to near-IR spectral range. However, this work shows that a balance can be achieved between a sufficiently high index of refraction (n> 2) and an acceptable optical loss (k<10−3) in nitride-rich SiNx of appropriate composition (x∼1.45). Bragg reflectors with a design wavelength at λo= 330 nm are used for validation. PECVD is used for sample preparation and experiments confirm that the spectral range available for use of SiNx-based optical microsystems extends to wavelengths as low as 300 nm.",

keywords = "CMOS compatibility, Integrated silicon optical microsystems, Near-UV optical filter, Optical MEMS technology, Silicon-nitride",

author = "Wolffenbuttel, {Reinoud F.} and Declan Winship and Yutao Qin and Yogesh Gianchandani and David Bilby and Visser, {Jaco H.}",

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doi = "10.1016/j.omx.2024.100348",

language = "English",

volume = "24",

journal = "Optical Materials: X",

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T1 - Optical properties of nitride-rich SiNx and its use in CMOS-compatible near-UV Bragg filter fabrication

AU - Wolffenbuttel, Reinoud F.

AU - Winship, Declan

AU - Qin, Yutao

AU - Gianchandani, Yogesh

AU - Bilby, David

AU - Visser, Jaco H.

PY - 2024

Y1 - 2024

N2 - Nitride-rich silicon-nitride (SiNx) is being explored for its potential as a suitable optical material for use in microsystems operating in the near-UV spectral range. Although silicon-rich SiNx is widely accepted as a CMOS-compatible dielectric and micromechanical material, its optical absorption limits application to the visible to near-IR spectral range. However, this work shows that a balance can be achieved between a sufficiently high index of refraction (n> 2) and an acceptable optical loss (k<10−3) in nitride-rich SiNx of appropriate composition (x∼1.45). Bragg reflectors with a design wavelength at λo= 330 nm are used for validation. PECVD is used for sample preparation and experiments confirm that the spectral range available for use of SiNx-based optical microsystems extends to wavelengths as low as 300 nm.

AB - Nitride-rich silicon-nitride (SiNx) is being explored for its potential as a suitable optical material for use in microsystems operating in the near-UV spectral range. Although silicon-rich SiNx is widely accepted as a CMOS-compatible dielectric and micromechanical material, its optical absorption limits application to the visible to near-IR spectral range. However, this work shows that a balance can be achieved between a sufficiently high index of refraction (n> 2) and an acceptable optical loss (k<10−3) in nitride-rich SiNx of appropriate composition (x∼1.45). Bragg reflectors with a design wavelength at λo= 330 nm are used for validation. PECVD is used for sample preparation and experiments confirm that the spectral range available for use of SiNx-based optical microsystems extends to wavelengths as low as 300 nm.

KW - CMOS compatibility

KW - Integrated silicon optical microsystems

KW - Near-UV optical filter

KW - Optical MEMS technology

KW - Silicon-nitride

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JO - Optical Materials: X

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M1 - 100348

ER -

Optical properties of nitride-rich SiN_x and its use in CMOS-compatible near-UV Bragg filter fabrication

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Keywords

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