Material and optical properties of low-temperature NH3-free PECVD SiNx layers for photonic applications
Material and optical properties of low-temperature NH3-free PECVD SiNx layers for photonic applications
SiNx layers intended for photonic applications are typically fabricated using LPCVD and PECVD. These techniques rely on high-temperature processing (>400 °C) to obtain low propagation losses. An alternative version of PECVD SiNx layers deposited at temperatures below 400°C with a recipe that does not use ammonia (NH3-free PECVD) was previously demonstrated to be a good option to fabricate strip waveguides with propagation losses <3dB cm-1. We have conducted a systematic investigation of the influence of the deposition parameters on the material and optical properties of NH3-free PECVD SiNx layers fabricated at 350°C using a design of experiments methodology. In particular, this paper discusses the effect of the SiH4 flow, RF power, chamber pressure and substrate on the structure, uniformity, roughness, deposition rate, refractive index, chemical composition, bond structure and H content of NH3-free PECVD SiNx layers. The results show that the properties and the propagation losses of the studied SiNx layers depend entirely on their compositional N/Si ratio, which is in fact the only parameter that can be directly tuned using the deposition parameters along with the film uniformity and deposition rate. These observations provide the means to optimise the propagation losses of the layers for photonic applications through the deposition parameters. In fact, we have been able to fabricate SiNx waveguides with H content <20%, good uniformity and propagation losses of 1.5 dB cm-1 at 1550nm and <1 dB.cm-1 at 1310nm. As a result, this study can potentially help optimise the properties of the studied SiNx layers for different applications.
1-12
Domínguez Bucio, Thalía
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Khokhar, Ali Z.
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Lacava, Cosimo
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Stanković, Stevan
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Mashanovich, Goran Z.
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Petropoulos, Periklis
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Gardes, Frederic Y.
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1 January 2017
Domínguez Bucio, Thalía
83b57799-c566-473c-9b53-92e9c50b4287
Khokhar, Ali Z.
2eedd1cc-8ac5-4f8e-be25-930bd3eae396
Lacava, Cosimo
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Stanković, Stevan
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Mashanovich, Goran Z.
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Petropoulos, Periklis
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Gardes, Frederic Y.
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Domínguez Bucio, Thalía, Khokhar, Ali Z., Lacava, Cosimo, Stanković, Stevan, Mashanovich, Goran Z., Petropoulos, Periklis and Gardes, Frederic Y.
(2017)
Material and optical properties of low-temperature NH3-free PECVD SiNx layers for photonic applications.
Journal of Physics D: Applied Physics, 50 (2), , [025106].
(doi:10.1088/1361-6463/50/2/025106).
Abstract
SiNx layers intended for photonic applications are typically fabricated using LPCVD and PECVD. These techniques rely on high-temperature processing (>400 °C) to obtain low propagation losses. An alternative version of PECVD SiNx layers deposited at temperatures below 400°C with a recipe that does not use ammonia (NH3-free PECVD) was previously demonstrated to be a good option to fabricate strip waveguides with propagation losses <3dB cm-1. We have conducted a systematic investigation of the influence of the deposition parameters on the material and optical properties of NH3-free PECVD SiNx layers fabricated at 350°C using a design of experiments methodology. In particular, this paper discusses the effect of the SiH4 flow, RF power, chamber pressure and substrate on the structure, uniformity, roughness, deposition rate, refractive index, chemical composition, bond structure and H content of NH3-free PECVD SiNx layers. The results show that the properties and the propagation losses of the studied SiNx layers depend entirely on their compositional N/Si ratio, which is in fact the only parameter that can be directly tuned using the deposition parameters along with the film uniformity and deposition rate. These observations provide the means to optimise the propagation losses of the layers for photonic applications through the deposition parameters. In fact, we have been able to fabricate SiNx waveguides with H content <20%, good uniformity and propagation losses of 1.5 dB cm-1 at 1550nm and <1 dB.cm-1 at 1310nm. As a result, this study can potentially help optimise the properties of the studied SiNx layers for different applications.
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Domínguez Bucio 2017 J. Phys. D Appl. Phys. 50 025106
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Accepted/In Press date: 4 November 2016
e-pub ahead of print date: 1 December 2016
Published date: 1 January 2017
Organisations:
Optoelectronics Research Centre
Identifiers
Local EPrints ID: 402364
URI: http://eprints.soton.ac.uk/id/eprint/402364
ISSN: 0022-3727
PURE UUID: 6921d0d7-ab28-49f7-8323-272aabd2b89a
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Date deposited: 29 Nov 2016 09:20
Last modified: 16 Mar 2024 02:58
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Author:
Ali Z. Khokhar
Author:
Cosimo Lacava
Author:
Stevan Stanković
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