Si-rich silicon nitride for nonlinear signal processing applications
Si-rich silicon nitride for nonlinear signal processing applications
Nonlinear silicon photonic devices have attracted considerable attention thanks to their ability to show large third-order nonlinear effects at moderate power levels allowing for all-optical signal processing functionalities in miniaturized components. Although significant efforts have been made and many nonlinear optical functions have already been demonstrated in this platform, the performance of nonlinear silicon photonic devices remains fundamentally limited at the telecom wavelength region due to the two photon absorption (TPA) and related effects. In this work, we propose an alternative CMOS-compatible platform, based on silicon-rich silicon nitride that can overcome this limitation. By carefully selecting the material deposition parameters, we show that both of the device linear and nonlinear properties can be tuned in order to exhibit the desired behaviour at the selected wavelength region. A rigorous and systematic fabrication and characterization campaign of different material compositions is presented, enabling us to demonstrate TPA-free CMOS-compatible waveguides with low linear loss (~1.5dB/cm) and enhanced Kerr nonlinear response (Re{γ} = 16 Wm-1). Thanks to these properties, our nonlinear waveguides are able to produce a pi nonlinear phase shift, paving the way for the development of practical devices for future optical communication applications.
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Lacava, Cosimo
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Stanković, Stevan
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Khokhar, Ali
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Domínguez Bucio, Thalía
83b57799-c566-473c-9b53-92e9c50b4287
Gardes, Frederic
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Reed, Graham
ca08dd60-c072-4d7d-b254-75714d570139
Richardson, David
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Petropoulos, Periklis
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2 February 2017
Lacava, Cosimo
a0a31a27-23ac-4a73-8bb4-2f02368fb8bd
Stanković, Stevan
13e8c464-b876-405a-b442-7c437a6eafd3
Khokhar, Ali
2eedd1cc-8ac5-4f8e-be25-930bd3eae396
Domínguez Bucio, Thalía
83b57799-c566-473c-9b53-92e9c50b4287
Gardes, Frederic
7a49fc6d-dade-4099-b016-c60737cb5bb2
Reed, Graham
ca08dd60-c072-4d7d-b254-75714d570139
Richardson, David
ebfe1ff9-d0c2-4e52-b7ae-c1b13bccdef3
Petropoulos, Periklis
522b02cc-9f3f-468e-bca5-e9f58cc9cad7
Lacava, Cosimo, Stanković, Stevan, Khokhar, Ali, Domínguez Bucio, Thalía, Gardes, Frederic, Reed, Graham, Richardson, David and Petropoulos, Periklis
(2017)
Si-rich silicon nitride for nonlinear signal processing applications.
Scientific Reports, 7 (22), .
(doi:10.1038/s41598-017-00062-6).
Abstract
Nonlinear silicon photonic devices have attracted considerable attention thanks to their ability to show large third-order nonlinear effects at moderate power levels allowing for all-optical signal processing functionalities in miniaturized components. Although significant efforts have been made and many nonlinear optical functions have already been demonstrated in this platform, the performance of nonlinear silicon photonic devices remains fundamentally limited at the telecom wavelength region due to the two photon absorption (TPA) and related effects. In this work, we propose an alternative CMOS-compatible platform, based on silicon-rich silicon nitride that can overcome this limitation. By carefully selecting the material deposition parameters, we show that both of the device linear and nonlinear properties can be tuned in order to exhibit the desired behaviour at the selected wavelength region. A rigorous and systematic fabrication and characterization campaign of different material compositions is presented, enabling us to demonstrate TPA-free CMOS-compatible waveguides with low linear loss (~1.5dB/cm) and enhanced Kerr nonlinear response (Re{γ} = 16 Wm-1). Thanks to these properties, our nonlinear waveguides are able to produce a pi nonlinear phase shift, paving the way for the development of practical devices for future optical communication applications.
Text
art%3A10.1038%2Fs41598-017-00062-6.pdf
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Accepted/In Press date: 16 December 2016
e-pub ahead of print date: 2 February 2017
Published date: 2 February 2017
Organisations:
Optoelectronics Research Centre
Identifiers
Local EPrints ID: 405416
URI: http://eprints.soton.ac.uk/id/eprint/405416
PURE UUID: 32d124a4-13ec-4427-aaea-2a31d87054f8
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Date deposited: 03 Feb 2017 14:02
Last modified: 16 Mar 2024 04:36
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