Microring resonator based on polarization multiplexing for simultaneous sensing of refractive index and temperature on silicon platform

Ou, Xiangpeng; Tang, Bo; Zhang, Peng; Li, Bin; Sun, Fubao; Liu, Ruonan; Huang, Kai; Xie, Le; Li, Zhihua; Yang, Yan

doi:10.1364/oe.459743

Cited by 4 publications

(2 citation statements)

References 36 publications

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“…In the case of temperature sensitivity, specifically, the high thermal expansion and thermo-optic coefficients of polymers which make them advantageous for optical temperature sensing applications 18 pose challenges when measuring other quantities. 20,21 First, temperature can be decoupled by measuring it. 10,22−24 By subtracting the contribution of the temperature, it becomes possible to extract the desired value accurately.…”

Section: Introductionmentioning

confidence: 99%

“…This versatility is both an advantage and a disadvantage, since it can lead to cross-sensitivity issues, resulting in erroneous readings of the measured values. In the case of temperature sensitivity, specifically, the high thermal expansion and thermo-optic coefficients of polymers which make them advantageous for optical temperature sensing applications pose challenges when measuring other quantities. , …”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Temperature Sensitivity Control of an Inkjet-Printed Optical Resonator on Pillar

Bianki,

Guertin,

Lemieux-Leduc

et al. 2024

ACS Appl. Mater. Interfaces

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We report a whispering gallery mode resonator on a pillar using inkjet printing combined with traditional microfabrication techniques. This approach enables several different polymers on the same chip for sensing applications. However, polymers inherently exhibit sensitivity to multiple stimuli. To mitigate temperature sensitivity, careful selection of design parameters is crucial. By precisely tuning the undercut-to-radius ratio of the resonator, a linear dependence in temperature sensitivity ranging from −41.5 pm/°C to 23.4 pm/°C, with a zero-crossing point at 47.6% is achieved. Consequently, it is feasible to fabricate sensing devices based on undercut microdroplets with minimal temperature sensitivity. The lowest measured temperature sensitivity obtained was 5.9 pm/°C, for a resonator with an undercut-to-radius ratio of 53%.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Temperature Sensitivity Control of an Inkjet-Printed Optical Resonator on Pillar

Bianki,

Guertin,

Lemieux-Leduc

et al. 2024

ACS Appl. Mater. Interfaces

View full text Add to dashboard Cite

show abstract

Design of a high-sensitivity graphene-silicon hybrid micro-disk in a square cavity whispering gallery mode biosensor

et al. 2023

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Zero-crosstalk silicon photonic refractive index sensor with subwavelength gratings

Ahmed,

Hasan,

Kim

et al. 2024

Nano Convergence

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Silicon photonic index sensors have received significant attention for label-free bio and gas-sensing applications, offering cost-effective and scalable solutions. Here, we introduce an ultra-compact silicon photonic refractive index sensor that leverages zero-crosstalk singularity responses enabled by subwavelength gratings. The subwavelength gratings are precisely engineered to achieve an anisotropic perturbation-led zero-crosstalk, resulting in a single transmission dip singularity in the spectrum that is independent of device length. The sensor is optimized for the transverse magnetic mode operation, where the subwavelength gratings are arranged perpendicular to the propagation direction to support a leaky-like mode and maximize the evanescent field interaction with the analyte space. Experimental results demonstrate a high wavelength sensitivity of − 410 nm/RIU and an intensity sensitivity of 395 dB/RIU, with a compact device footprint of approximately 82.8 μm2. Distinct from other resonant and interferometric sensors, our approach provides an FSR-free single-dip spectral response on a small device footprint, overcoming common challenges faced by traditional sensors, such as signal/phase ambiguity, sensitivity fading, limited detection range, and the necessity for large device footprints. This makes our sensor ideal for simplified intensity interrogation. The proposed sensor holds promise for a range of on-chip refractive index sensing applications, from gas to biochemical detection, representing a significant step towards efficient and miniaturized photonic sensing solutions. Graphical Abstract

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Microring resonator based on polarization multiplexing for simultaneous sensing of refractive index and temperature on silicon platform

Cited by 4 publications

References 36 publications

Temperature Sensitivity Control of an Inkjet-Printed Optical Resonator on Pillar

Temperature Sensitivity Control of an Inkjet-Printed Optical Resonator on Pillar

Design of a high-sensitivity graphene-silicon hybrid micro-disk in a square cavity whispering gallery mode biosensor

Zero-crosstalk silicon photonic refractive index sensor with subwavelength gratings

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