Miniaturized silicon photonics multi-sensor operating at high temperatures for use in composite materials industrial applications

Zervos, Charalampos; Poulopoulos, Giannis; Missinne, Jeroen; Szaj, Michal; Avramopoulos, H.

doi:10.1117/12.2606053

Cited by 4 publications

(5 citation statements)

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“…When fitting a linear function through the measured data, a sensitivity of 73 pm/°C was found, which was very close to the simulated sensitivity (i.e. 70 pm/°C) for Bragg gratings in the current technology [13]. Because a Bragg grating sensor with a different pitch (i.e.…”

Section: Proof-of-concept Sensor Demonstrationsupporting

confidence: 77%

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Compact packaged silicon photonic Bragg grating sensor based on a ball lens interface

Missinne

Geudens²,

Put³

et al. 2023

Optics & Laser Technology

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Section: Proof-of-concept Sensor Demonstrationsupporting

confidence: 77%

“…Those variations yield nearly identical reflection spectra, but 5.2 nm blue-shifted or red-shifted in Bragg wavelength respectively. The simulated shift in Bragg wavelength as a function of temperature was previously reported to be 70 pm/°C [13] for the adopted technology.…”

Section: Bragg Grating Sensor Designmentioning

confidence: 68%

Compact packaged silicon photonic Bragg grating sensor based on a ball lens interface

Missinne

Geudens²,

Put³

et al. 2023

Optics & Laser Technology

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“…The influence of the design parameters (corrugation width, number of periods, pitch, effective index, and fill factor) on the spectral response of the Bragg grating can be studied analytically 17 or using the eigenmode expansion propagation solver (Ansys Lumerical) as detailed in Refs. 13 and 14. In summary, increasing the fill factor has a minor influence on the Bragg wavelength, increasing the number of periods increases peak reflectivity, and increasing the corrugation width increases the bandwidth.…”

Section: Process From Design To Packaged Sensormentioning

confidence: 93%

“…The design of the silicon Bragg grating sensor was detailed in Refs. 13 and 14, and a high-level overview of the packaging process was reported in Ref. 9.…”

Section: Introductionmentioning

confidence: 99%

Silicon photonic temperature sensor: from photonic integrated chip to fully packaged miniature probe

Missinne,

Geudens,

Poulopoulos

et al. 2023

J. Optical Microsystems

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With the increased interest in silicon photonics, integration and packaging technologies are essential to transforming photonic integrated circuits (PICs) into functional photonic systems. We describe in detail the process to obtain a fully packaged miniature photonic temperature sensor starting from bare PIC dies having Bragg grating sensors in a silicon waveguide. It is also shown that PICs fabricated via multiproject wafer services can show some variability, e.g., in the effective index, which has significant impact on the device functionality (Bragg wavelength) and optical interface (red-shifted grating coupler spectra at default coupling angles). To obtain a final sensor device that is as small as possible the PIC is interfaced from the back side using a 300 μm ball lens. Furthermore, this ensures that the top surface remains clear of any interfacing fibers. Based on this optical interfacing concept, we developed a solution for integrating a 1 mm × 1 mm sensor PIC with a single-mode fiber and packaging it in a 1.5 mm inner-diameter metal protective tube. The accurate position of the ball lens is ensured using a laser-fabricated fused silica precision holder. It is shown that the additional insertion loss caused by the ball lens interface is very limited. A packaged sensor was achieved by sequentially mounting the holder on a ceramic ferrule and then the PIC on the holder and finally gluing a protective metal tube surrounding the assembly, taking care that the PIC surface is flush with the end face of the tube. We demonstrated this concept by realizing a packaged phase-shifted silicon Bragg grating temperature sensor operating around 1550 nm, which could be read out in reflection using a commercial interrogator. A temperature sensitivity of 73 pm∕°C was found, and we demonstrated sensor functionality up to 180°C.

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“…In our previous publications, we have described in detail how the grating pitch, corrugation width etc. have an impact on the Bragg grating response [6,7]. Firstly, due to the large refractive index contrast, the bandwidth of the reflection peak is much larger (several nanometer) than in optical fibers (<<1 nm).…”

Section: Concept Of the Compact Silicon Photonic Sensor Probementioning

confidence: 99%

A fully packaged silicon photonic Bragg grating temperature sensor with a compact back side interface based on a ball lens

Missinne

Geudens

Put

et al. 2023

Silicon Photonics XVIII

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With the increased interest in silicon photonics, smart integration and packaging technologies are essential to transform photonic integrated circuits (PICs) into functional photonic systems. Especially for sensing, the currently existing standard packaging technologies are too expensive and bulky. We developed a solution for integrating a 1 mm x 1 mm sensor PIC with a single mode fiber and packaging it in a 1.5 mm inner-diameter metal protective tube. The concept relies on interfacing a grating coupler with a fiber from the back side of the PIC employing a 300 µm ball lens mounted in a laser-fabricated fused silica precision holder. It is shown that the additional insertion loss caused by the ball lens interface is very limited. A packaged sensor was achieved by sequentially mounting the holder on a ceramic ferrule, then the PIC on the holder and finally gluing a metal tube surrounding the assembly, taking care that the PIC surface is flush with the end face of the tube. The back side fiber interface ensures that the PIC's surface remains accessible for sensing, while the tube protects the fiber-to-PIC interface. We demonstrated this concept by realizing a packaged phase shifted silicon Bragg grating temperature sensor operating around 1550 nm, which could be read out in reflection using a commercial interrogator. A temperature sensitivity of 73 pm/°C was found, and we demonstrated sensor functionality up to 180°C.

show abstract

Miniaturized silicon photonics multi-sensor operating at high temperatures for use in composite materials industrial applications

Cited by 4 publications

References 0 publications

Compact packaged silicon photonic Bragg grating sensor based on a ball lens interface

Compact packaged silicon photonic Bragg grating sensor based on a ball lens interface

Silicon photonic temperature sensor: from photonic integrated chip to fully packaged miniature probe

A fully packaged silicon photonic Bragg grating temperature sensor with a compact back side interface based on a ball lens

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