Monolithic photonic integration technology platform and devices at wavelengths beyond 2 μm for gas spectroscopy applications

S. Latkowski, P.J. van Veldhoven, A. Hänsel, D. D'Agostino, H. Rabbani-Haghighi, B. Docter, N. 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

Uittreksel

In this paper a generic monolithic photonic integration technology platform and tunable laser devices for gas sensing applications at 2 μm will be presented. The basic set of long wavelength optical functions which is fundamental for a generic photonic integration approach is realized using planar, but-joint, active-passive integration on indium phosphide substrate with active components based on strained InGaAs quantum wells. Using this limited set of basic building blocks a novel geometry, widely tunable laser source was designed and fabricated within the first long wavelength multiproject wafer run. The fabricated laser operates around 2027 nm, covers a record tuning range of 31 nm and is successfully employed in absorption measurements of carbon dioxide. These results demonstrate a fully functional long wavelength photonic integrated circuit that operates at these wavelengths. Moreover, the process steps and material system used for the long wavelength technology are almost identical to the ones which are used in the technology process at 1.5μm which makes it straightforward and hassle-free to transfer to the photonic foundries with existing fabrication lines. The changes from the 1550 nm technology and the trade-offs made in the building block design and layer stack will be discussed.

Originele taal-2Engels
TitelIntegrated Optics
SubtitelDevices, Materials, and Technologies XXI
Plaats van productieBellingham
UitgeverijSPIE
ISBN van elektronische versie9781510606531
DOI's
StatusGepubliceerd - 1 jan 2017
EvenementIntegrated Optics: Devices, Materials, and Technologies XXI - San Francisco, Verenigde Staten van Amerika
Duur: 30 jan 20171 feb 2017

Congres

CongresIntegrated Optics: Devices, Materials, and Technologies XXI
LandVerenigde Staten van Amerika
StadSan Francisco
Periode30/01/171/02/17

Vingerafdruk

Photonic integration technology
gas spectroscopy
Photonics
Spectroscopy
platforms
Gases
photonics
Wavelength
Tunable Laser
Laser tuning
wavelengths
tunable lasers
Building Blocks
Photonic Integrated Circuits
Indium phosphide
foundries
indium phosphides
InGaAs
Block Design
Quantum Well

Citeer dit

Latkowski, S., van Veldhoven, P. J., Hänsel, A., D'Agostino, D., Rabbani-Haghighi, H., Docter, B., ... Bente, E. A. J. M. (2017). Monolithic photonic integration technology platform and devices at wavelengths beyond 2 μm for gas spectroscopy applications. In Integrated Optics: Devices, Materials, and Technologies XXI [101060Q] Bellingham: SPIE. https://doi.org/10.1117/12.2256604
Latkowski, S. ; van Veldhoven, P.J. ; Hänsel, A. ; D'Agostino, D. ; Rabbani-Haghighi, H. ; Docter, B. ; Bhattacharya, N. ; Thijs, P.J.A. ; Ambrosius, H.P.M.M. ; Smit, M.K. ; Williams, K.A. ; Bente, E.A.J.M. / Monolithic photonic integration technology platform and devices at wavelengths beyond 2 μm for gas spectroscopy applications. Integrated Optics: Devices, Materials, and Technologies XXI. Bellingham : SPIE, 2017.
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abstract = "In this paper a generic monolithic photonic integration technology platform and tunable laser devices for gas sensing applications at 2 μm will be presented. The basic set of long wavelength optical functions which is fundamental for a generic photonic integration approach is realized using planar, but-joint, active-passive integration on indium phosphide substrate with active components based on strained InGaAs quantum wells. Using this limited set of basic building blocks a novel geometry, widely tunable laser source was designed and fabricated within the first long wavelength multiproject wafer run. The fabricated laser operates around 2027 nm, covers a record tuning range of 31 nm and is successfully employed in absorption measurements of carbon dioxide. These results demonstrate a fully functional long wavelength photonic integrated circuit that operates at these wavelengths. Moreover, the process steps and material system used for the long wavelength technology are almost identical to the ones which are used in the technology process at 1.5μm which makes it straightforward and hassle-free to transfer to the photonic foundries with existing fabrication lines. The changes from the 1550 nm technology and the trade-offs made in the building block design and layer stack will be discussed.",
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Latkowski, S, van Veldhoven, PJ, Hänsel, A, D'Agostino, D, Rabbani-Haghighi, H, Docter, B, Bhattacharya, N, Thijs, PJA, Ambrosius, HPMM, Smit, MK, Williams, KA & Bente, EAJM 2017, Monolithic photonic integration technology platform and devices at wavelengths beyond 2 μm for gas spectroscopy applications. in Integrated Optics: Devices, Materials, and Technologies XXI., 101060Q, SPIE, Bellingham, San Francisco, Verenigde Staten van Amerika, 30/01/17. https://doi.org/10.1117/12.2256604

Monolithic photonic integration technology platform and devices at wavelengths beyond 2 μm for gas spectroscopy applications. / Latkowski, S.; van Veldhoven, P.J.; Hänsel, A.; D'Agostino, D.; Rabbani-Haghighi, H.; Docter, B.; Bhattacharya, N.; Thijs, P.J.A.; Ambrosius, H.P.M.M.; Smit, M.K.; Williams, K.A.; Bente, E.A.J.M.

Integrated Optics: Devices, Materials, and Technologies XXI. Bellingham : SPIE, 2017. 101060Q.

Onderzoeksoutput: Hoofdstuk in Boek/Rapport/CongresprocedureConferentiebijdrageAcademicpeer review

TY - GEN

T1 - Monolithic photonic integration technology platform and devices at wavelengths beyond 2 μm for gas spectroscopy applications

AU - Latkowski, S.

AU - van Veldhoven, P.J.

AU - Hänsel, A.

AU - D'Agostino, D.

AU - Rabbani-Haghighi, H.

AU - Docter, B.

AU - Bhattacharya, N.

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 - In this paper a generic monolithic photonic integration technology platform and tunable laser devices for gas sensing applications at 2 μm will be presented. The basic set of long wavelength optical functions which is fundamental for a generic photonic integration approach is realized using planar, but-joint, active-passive integration on indium phosphide substrate with active components based on strained InGaAs quantum wells. Using this limited set of basic building blocks a novel geometry, widely tunable laser source was designed and fabricated within the first long wavelength multiproject wafer run. The fabricated laser operates around 2027 nm, covers a record tuning range of 31 nm and is successfully employed in absorption measurements of carbon dioxide. These results demonstrate a fully functional long wavelength photonic integrated circuit that operates at these wavelengths. Moreover, the process steps and material system used for the long wavelength technology are almost identical to the ones which are used in the technology process at 1.5μm which makes it straightforward and hassle-free to transfer to the photonic foundries with existing fabrication lines. The changes from the 1550 nm technology and the trade-offs made in the building block design and layer stack will be discussed.

AB - In this paper a generic monolithic photonic integration technology platform and tunable laser devices for gas sensing applications at 2 μm will be presented. The basic set of long wavelength optical functions which is fundamental for a generic photonic integration approach is realized using planar, but-joint, active-passive integration on indium phosphide substrate with active components based on strained InGaAs quantum wells. Using this limited set of basic building blocks a novel geometry, widely tunable laser source was designed and fabricated within the first long wavelength multiproject wafer run. The fabricated laser operates around 2027 nm, covers a record tuning range of 31 nm and is successfully employed in absorption measurements of carbon dioxide. These results demonstrate a fully functional long wavelength photonic integrated circuit that operates at these wavelengths. Moreover, the process steps and material system used for the long wavelength technology are almost identical to the ones which are used in the technology process at 1.5μm which makes it straightforward and hassle-free to transfer to the photonic foundries with existing fabrication lines. The changes from the 1550 nm technology and the trade-offs made in the building block design and layer stack will be discussed.

KW - Gas spectroscopy

KW - Photonic integrated circuits

KW - Semiconductor laser

KW - Tunable laser

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U2 - 10.1117/12.2256604

DO - 10.1117/12.2256604

M3 - Conference contribution

AN - SCOPUS:85020279046

BT - Integrated Optics

PB - SPIE

CY - Bellingham

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Latkowski S, van Veldhoven PJ, Hänsel A, D'Agostino D, Rabbani-Haghighi H, Docter B et al. Monolithic photonic integration technology platform and devices at wavelengths beyond 2 μm for gas spectroscopy applications. In Integrated Optics: Devices, Materials, and Technologies XXI. Bellingham: SPIE. 2017. 101060Q https://doi.org/10.1117/12.2256604