Fully integrated and broadband Si-rich silicon nitride wavelength converter based on Bragg scattering intermodal four-wave mixing

Valerio Vitali; Thalía Domínguez Bucio; Liu Hao; José Manuel Luque González; Francisco Jurado-Romero; Alejandro Ortega-Moñux; Glenn Churchill; James C. Gates; James Hillier; Nikolaos Kalfagiannis; Daniele Melati; Jens H. Schmid; Ilaria Cristiani; Pavel Cheben; J. Gonzalo Wangüemert-Pérez; Íñigo Molina-Fernández; Frederic Gardes; Cosimo Lacava; Periklis Petropoulos

doi:10.1364/PRJ.506691

Fully integrated and broadband Si-rich silicon nitride wavelength converter based on Bragg scattering intermodal four-wave mixing

Valerio Vitali (Corresponding author), Thalía Domínguez Bucio, Liu Hao, José Manuel Luque González, Francisco Jurado-Romero, Alejandro Ortega-Moñux, Glenn Churchill, James C. Gates, James Hillier, Nikolaos Kalfagiannis, Daniele Melati, Jens H. Schmid, Ilaria Cristiani, Pavel Cheben, J. Gonzalo Wangüemert-Pérez, Íñigo Molina-Fernández, Frederic Gardes, Cosimo Lacava, Periklis Petropoulos

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Abstract

Intermodal four-wave mixing (FWM) processes have recently attracted significant interest for all-optical signal processing applications thanks to the possibility to control the propagation properties of waves exciting distinct spatial modes of the same waveguide. This allows, in principle, to place signals in different spectral regions and satisfy the phase matching condition over considerably larger bandwidths compared to intramodal processes. However, the demonstrations reported so far have shown a limited bandwidth and suffered from the lack of on-chip components designed for broadband manipulation of different modes. We demonstrate here a silicon-rich silicon nitride wavelength converter based on Bragg scattering intermodal FWM, which integrates mode conversion, multiplexing and de-multiplexing functionalities on-chip. The system enables wavelength conversion between pump waves and a signal located in different telecommunication bands (separated by 60 nm) with a 3 dB bandwidth exceeding 70 nm, which represents, to our knowledge, the widest bandwidth ever achieved in an intermodal FWM-based system.

Original language	English
Pages (from-to)	A1-A10
Number of pages	10
Journal	Photonics Research
Volume	12
Issue number	3
DOIs	https://doi.org/10.1364/PRJ.506691
Publication status	Published - Mar 2024

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© 2024 Optica Publishing Group (formerly OSA). All rights reserved.

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Vitali, V., Bucio, T. D., Hao, L., González, J. M. L., Jurado-Romero, F., Ortega-Moñux, A., Churchill, G., Gates, J. C., Hillier, J., Kalfagiannis, N., Melati, D., Schmid, J. H., Cristiani, I., Cheben, P., Wangüemert-Pérez, J. G., Molina-Fernández, Í., Gardes, F., Lacava, C., & Petropoulos, P. (2024). Fully integrated and broadband Si-rich silicon nitride wavelength converter based on Bragg scattering intermodal four-wave mixing. Photonics Research, 12(3), A1-A10. https://doi.org/10.1364/PRJ.506691

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title = "Fully integrated and broadband Si-rich silicon nitride wavelength converter based on Bragg scattering intermodal four-wave mixing",

abstract = "Intermodal four-wave mixing (FWM) processes have recently attracted significant interest for all-optical signal processing applications thanks to the possibility to control the propagation properties of waves exciting distinct spatial modes of the same waveguide. This allows, in principle, to place signals in different spectral regions and satisfy the phase matching condition over considerably larger bandwidths compared to intramodal processes. However, the demonstrations reported so far have shown a limited bandwidth and suffered from the lack of on-chip components designed for broadband manipulation of different modes. We demonstrate here a silicon-rich silicon nitride wavelength converter based on Bragg scattering intermodal FWM, which integrates mode conversion, multiplexing and de-multiplexing functionalities on-chip. The system enables wavelength conversion between pump waves and a signal located in different telecommunication bands (separated by 60 nm) with a 3 dB bandwidth exceeding 70 nm, which represents, to our knowledge, the widest bandwidth ever achieved in an intermodal FWM-based system.",

author = "Valerio Vitali and Bucio, {Thal{\'i}a Dom{\'i}nguez} and Liu Hao and Gonz{\'a}lez, {Jos{\'e} Manuel Luque} and Francisco Jurado-Romero and Alejandro Ortega-Mo{\~n}ux and Glenn Churchill and Gates, {James C.} and James Hillier and Nikolaos Kalfagiannis and Daniele Melati and Schmid, {Jens H.} and Ilaria Cristiani and Pavel Cheben and Wang{\"u}emert-P{\'e}rez, {J. Gonzalo} and {\'I}{\~n}igo Molina-Fern{\'a}ndez and Frederic Gardes and Cosimo Lacava and Periklis Petropoulos",

year = "2024",

month = mar,

doi = "10.1364/PRJ.506691",

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Vitali, V, Bucio, TD, Hao, L, González, JML, Jurado-Romero, F, Ortega-Moñux, A, Churchill, G, Gates, JC, Hillier, J, Kalfagiannis, N, Melati, D, Schmid, JH, Cristiani, I, Cheben, P, Wangüemert-Pérez, JG, Molina-Fernández, Í, Gardes, F, Lacava, C & Petropoulos, P 2024, 'Fully integrated and broadband Si-rich silicon nitride wavelength converter based on Bragg scattering intermodal four-wave mixing', Photonics Research, vol. 12, no. 3, pp. A1-A10. https://doi.org/10.1364/PRJ.506691

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T1 - Fully integrated and broadband Si-rich silicon nitride wavelength converter based on Bragg scattering intermodal four-wave mixing

AU - Vitali, Valerio

AU - Bucio, Thalía Domínguez

AU - Hao, Liu

AU - González, José Manuel Luque

AU - Jurado-Romero, Francisco

AU - Ortega-Moñux, Alejandro

AU - Churchill, Glenn

AU - Gates, James C.

AU - Hillier, James

AU - Kalfagiannis, Nikolaos

AU - Melati, Daniele

AU - Schmid, Jens H.

AU - Cristiani, Ilaria

AU - Cheben, Pavel

AU - Wangüemert-Pérez, J. Gonzalo

AU - Molina-Fernández, Íñigo

AU - Gardes, Frederic

AU - Lacava, Cosimo

AU - Petropoulos, Periklis

PY - 2024/3

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AB - Intermodal four-wave mixing (FWM) processes have recently attracted significant interest for all-optical signal processing applications thanks to the possibility to control the propagation properties of waves exciting distinct spatial modes of the same waveguide. This allows, in principle, to place signals in different spectral regions and satisfy the phase matching condition over considerably larger bandwidths compared to intramodal processes. However, the demonstrations reported so far have shown a limited bandwidth and suffered from the lack of on-chip components designed for broadband manipulation of different modes. We demonstrate here a silicon-rich silicon nitride wavelength converter based on Bragg scattering intermodal FWM, which integrates mode conversion, multiplexing and de-multiplexing functionalities on-chip. The system enables wavelength conversion between pump waves and a signal located in different telecommunication bands (separated by 60 nm) with a 3 dB bandwidth exceeding 70 nm, which represents, to our knowledge, the widest bandwidth ever achieved in an intermodal FWM-based system.

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JF - Photonics Research

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Fully integrated and broadband Si-rich silicon nitride wavelength converter based on Bragg scattering intermodal four-wave mixing

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