Long wavelength monolithic photonic integration technology for gas sensing applications

S. Latkowski, A. Hansel, D. D'Agostino, P.J. van Veldhoven, H. Rabbani Haghighi, B. Docter, Nandini Bhattacharya, P.J.A. Thijs, H.P.M.M. Ambrosius, M.K. Smit, K.A. Williams, E.A.J.M. Bente

Onderzoeksoutput: Hoofdstuk in Boek/Rapport/CongresprocedureConferentiebijdrageAcademicpeer review

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Uittreksel

Progress on the development of a long wavelength (~2 μm) generic monolithic photonic integration technology on indium phosphide substrate and a novel concept of a tunable laser realized as a photonic integrated circuit using such technology are presented. Insights into the development of active and passive waveguide structures which are used to define a limited set of on-chip functionalities in the form of building blocks will be given. A novel tunable laser was proposed and designed using such predefined set of basic building blocks. The laser geometry features an intra-cavity wavelength tuning mechanism based on asymmetric Mach-Zehnder interferometers in a nested configuration. The photonic integrated circuit chip was fabricated within the first long wavelength multi-project wafer run. The experimental evaluations of the fabricated device show a record tuning range of 31 nm around 2027 nm and successful measurements of a 0.86 GHz wide absorption line of carbon dioxide. These results provide a demonstration of a fully functional photonic integrated circuit operating at wavelengths that are much longer than those in the typical telecommunication windows as well as the use of indium phosphide based generic photonic integration technologies for gas sensing applications.
Originele taal-2Engels
TitelTransparent Optical Networks (ICTON), 2016 18th International Conference on
UitgeverijInstitute of Electrical and Electronics Engineers
Aantal pagina's4
DOI's
StatusGepubliceerd - jul 2016
Evenement18th International Conference on Transparent Optical Networks (ICTON 2016) - University of Trento, Trento, Italië
Duur: 10 jul 201614 jul 2016
Congresnummer: 18
https://icton2016.fbk.eu/

Congres

Congres18th International Conference on Transparent Optical Networks (ICTON 2016)
Verkorte titelICTOM2016
LandItalië
StadTrento
Periode10/07/1614/07/16
Internet adres

Vingerafdruk

photonics
integrated circuits
indium phosphides
gases
wavelengths
tunable lasers
chips
tuning
Mach-Zehnder interferometers
carbon dioxide
telecommunication
wafers
waveguides
cavities
evaluation
geometry
configurations
lasers

Citeer dit

Latkowski, S., Hansel, A., D'Agostino, D., van Veldhoven, P. J., Rabbani Haghighi, H., Docter, B., ... Bente, E. A. J. M. (2016). Long wavelength monolithic photonic integration technology for gas sensing applications. In Transparent Optical Networks (ICTON), 2016 18th International Conference on [We.B5.4] Institute of Electrical and Electronics Engineers. https://doi.org/10.1109/ICTON.2016.7550555
Latkowski, S. ; Hansel, A. ; D'Agostino, D. ; van Veldhoven, P.J. ; Rabbani Haghighi, H. ; Docter, B. ; Bhattacharya, Nandini ; Thijs, P.J.A. ; Ambrosius, H.P.M.M. ; Smit, M.K. ; Williams, K.A. ; Bente, E.A.J.M. / Long wavelength monolithic photonic integration technology for gas sensing applications. Transparent Optical Networks (ICTON), 2016 18th International Conference on. Institute of Electrical and Electronics Engineers, 2016.
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title = "Long wavelength monolithic photonic integration technology for gas sensing applications",
abstract = "Progress on the development of a long wavelength (~2 μm) generic monolithic photonic integration technology on indium phosphide substrate and a novel concept of a tunable laser realized as a photonic integrated circuit using such technology are presented. Insights into the development of active and passive waveguide structures which are used to define a limited set of on-chip functionalities in the form of building blocks will be given. A novel tunable laser was proposed and designed using such predefined set of basic building blocks. The laser geometry features an intra-cavity wavelength tuning mechanism based on asymmetric Mach-Zehnder interferometers in a nested configuration. The photonic integrated circuit chip was fabricated within the first long wavelength multi-project wafer run. The experimental evaluations of the fabricated device show a record tuning range of 31 nm around 2027 nm and successful measurements of a 0.86 GHz wide absorption line of carbon dioxide. These results provide a demonstration of a fully functional photonic integrated circuit operating at wavelengths that are much longer than those in the typical telecommunication windows as well as the use of indium phosphide based generic photonic integration technologies for gas sensing applications.",
author = "S. Latkowski and A. Hansel and D. D'Agostino and {van Veldhoven}, P.J. and {Rabbani Haghighi}, H. and B. Docter and Nandini Bhattacharya and P.J.A. Thijs and H.P.M.M. Ambrosius and M.K. Smit and K.A. Williams and E.A.J.M. Bente",
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Latkowski, S, Hansel, A, D'Agostino, D, van Veldhoven, PJ, Rabbani Haghighi, H, Docter, B, Bhattacharya, N, Thijs, PJA, Ambrosius, HPMM, Smit, MK, Williams, KA & Bente, EAJM 2016, Long wavelength monolithic photonic integration technology for gas sensing applications. in Transparent Optical Networks (ICTON), 2016 18th International Conference on., We.B5.4, Institute of Electrical and Electronics Engineers, Trento, Italië, 10/07/16. https://doi.org/10.1109/ICTON.2016.7550555

Long wavelength monolithic photonic integration technology for gas sensing applications. / Latkowski, S.; Hansel, A.; D'Agostino, D.; van Veldhoven, P.J.; Rabbani Haghighi, H.; Docter, B.; Bhattacharya, Nandini; Thijs, P.J.A.; Ambrosius, H.P.M.M.; Smit, M.K.; Williams, K.A.; Bente, E.A.J.M.

Transparent Optical Networks (ICTON), 2016 18th International Conference on. Institute of Electrical and Electronics Engineers, 2016. We.B5.4.

Onderzoeksoutput: Hoofdstuk in Boek/Rapport/CongresprocedureConferentiebijdrageAcademicpeer review

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T1 - Long wavelength monolithic photonic integration technology for gas sensing applications

AU - Latkowski, S.

AU - Hansel, A.

AU - D'Agostino, D.

AU - van Veldhoven, P.J.

AU - Rabbani Haghighi, H.

AU - Docter, B.

AU - Bhattacharya, Nandini

AU - Thijs, P.J.A.

AU - Ambrosius, H.P.M.M.

AU - Smit, M.K.

AU - Williams, K.A.

AU - Bente, E.A.J.M.

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N2 - Progress on the development of a long wavelength (~2 μm) generic monolithic photonic integration technology on indium phosphide substrate and a novel concept of a tunable laser realized as a photonic integrated circuit using such technology are presented. Insights into the development of active and passive waveguide structures which are used to define a limited set of on-chip functionalities in the form of building blocks will be given. A novel tunable laser was proposed and designed using such predefined set of basic building blocks. The laser geometry features an intra-cavity wavelength tuning mechanism based on asymmetric Mach-Zehnder interferometers in a nested configuration. The photonic integrated circuit chip was fabricated within the first long wavelength multi-project wafer run. The experimental evaluations of the fabricated device show a record tuning range of 31 nm around 2027 nm and successful measurements of a 0.86 GHz wide absorption line of carbon dioxide. These results provide a demonstration of a fully functional photonic integrated circuit operating at wavelengths that are much longer than those in the typical telecommunication windows as well as the use of indium phosphide based generic photonic integration technologies for gas sensing applications.

AB - Progress on the development of a long wavelength (~2 μm) generic monolithic photonic integration technology on indium phosphide substrate and a novel concept of a tunable laser realized as a photonic integrated circuit using such technology are presented. Insights into the development of active and passive waveguide structures which are used to define a limited set of on-chip functionalities in the form of building blocks will be given. A novel tunable laser was proposed and designed using such predefined set of basic building blocks. The laser geometry features an intra-cavity wavelength tuning mechanism based on asymmetric Mach-Zehnder interferometers in a nested configuration. The photonic integrated circuit chip was fabricated within the first long wavelength multi-project wafer run. The experimental evaluations of the fabricated device show a record tuning range of 31 nm around 2027 nm and successful measurements of a 0.86 GHz wide absorption line of carbon dioxide. These results provide a demonstration of a fully functional photonic integrated circuit operating at wavelengths that are much longer than those in the typical telecommunication windows as well as the use of indium phosphide based generic photonic integration technologies for gas sensing applications.

U2 - 10.1109/ICTON.2016.7550555

DO - 10.1109/ICTON.2016.7550555

M3 - Conference contribution

BT - Transparent Optical Networks (ICTON), 2016 18th International Conference on

PB - Institute of Electrical and Electronics Engineers

ER -

Latkowski S, Hansel A, D'Agostino D, van Veldhoven PJ, Rabbani Haghighi H, Docter B et al. Long wavelength monolithic photonic integration technology for gas sensing applications. In Transparent Optical Networks (ICTON), 2016 18th International Conference on. Institute of Electrical and Electronics Engineers. 2016. We.B5.4 https://doi.org/10.1109/ICTON.2016.7550555