Optical hydrogen sensing with high-Q guided-mode resonance of Al2O3/WO3/Pd nanostructure

Kulikova, Daria P.; Sgibnev, Yevgeniy; Yankovskii, Georgiy M.; Chubchev, Eugeny D.; Lotkov, Evgeniy S.; Ezenkova, D. A.; Dobronosova, Alina A.; Baburin, Aleksandr S.; Rodionov, Ilya A.; Nechepurenko, Igor A.; Baryshev, A. V.; Dorofeenko, A. V.

doi:10.1038/s41598-023-28204-z

Cited by 8 publications

(2 citation statements)

References 54 publications

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“…Optical sensing of materials is also a quite vast area where the optical radiation interacts with the analyte to generate a change in some properties of light. [15][16][17][18] The excitation of plasmonic resonances at the interface of Figure 1. Graphical layout of a device that includes a photon sieve as a permeable DOE.…”

Section: Introductionmentioning

confidence: 99%

Permeable diffractive optical elements for real-time sensing of running fluids

Pastor-Villarrubia¹,

Soria-García

Hoyo

et al. 2023

Optical Sensors 2023

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The real-time monitoring of physical and chemical parameters in running fluids is of importance for biomedical, biochemical, and environmental applications, such as the presence of biomarkers or chemomarkers, or the departure from some preset values of critical parameters. In this contribution we present a new generation of Permeable Diffractive Optical Elements (PDOE) based on photon sieves. In brief, the PDOE is made of passing holes properly placed on specific locations on a rigid surface. This arrangement makes PDOEs ideal to work with running fluids. Our PDOE is optimized maximizing the irradiance at is focal plane, maintaining an appropriate permeability ratio. The starting point is the classical Fresnel zone distribution. We have used two different optimization strategies to design a working PDOE: i) Particle Swarm Optimization has been applied to modify the distribution of holes on the PDOE simultaneously considering all of them; ii) an iterative minimization algorithm adding one hole at the time until filling the PDOE aperture. Both optimization algorithms generate focal spots that are compared to choose the design better suited for the proposed application. Once the PDOE is optimized and fabricated, the surface of the remaining rigid structure is nanostructured (for example using Laser Induced Periodic Surface Structures), or functionalized, to provide specific sensing capabilities. In addition, the PDOE is integrated within a pipe where the fluid under analysis circulates through. A proposal for the optoelectronic assembly of the device-including auxiliary optical elements, light sources, and detectors - is also presented in this contribution.

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Section: Introductionmentioning

confidence: 99%

Permeable diffractive optical elements for real-time sensing of running fluids

Pastor-Villarrubia¹,

Soria-García

Hoyo

et al. 2023

Optical Sensors 2023

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“…Photonic refractive index sensors are well established as a choice technology for the instantaneous, label-free, contactless, and highly sensitive characterization of many technologically relevant analytes. There is high demand for such sensors in the biological, chemical, environmental, defense, transport, and food industries, both for the detection of specific targets and also in the area of process control. − Refractive index sensors typically employ the overlap of the evanescent tail of a guided mode with the analyte to detect small changes, either with or without a binder molecule attached to the surface for increased specificity. , The implementation of such sensors in a real industrial environment is limited, however, by their sensitivity to other external influences such as mechanical vibrations and temperature variations; these external influences generate significant noise, which may easily screen the desired signal(s). For example, mechanical vibrations often limit the use of sensors to vibration-free environments, − which are impractical for applications in the field such as in industrial plants.…”

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confidence: 99%

Noise Tolerant Photonic Bowtie Grating Environmental Sensor

Li,

Suliali,

Sahoo

et al. 2024

ACS Sens.

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Resonant photonic refractive index sensors have made major advances based on their high sensitivity and contact-less readout capability, which is advantageous in many areas of science and technology. A major issue for the technological implementation of such sensors is their response to external influences, such as vibrations and temperature variations; the more sensitive a sensor, the more susceptible it also becomes to external influences. Here, we introduce a novel bowtieshaped sensor that is highly responsive to refractive index variations while compensating for temperature changes and mechanical (linear and angular) vibrations. We exemplify its capability by demonstrating the detection of salinity to a precision of 0.1%, corresponding to 2.3 × 10 −4 refractive index units in the presence of temperature fluctuations and mechanical vibrations. As a second exemplar, we detected bacteria growth in a pilot industrial environment. Our results demonstrate that it is possible to translate high sensitivity resonant photonic refractive index sensors into real-world environments.

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Silicon Nitride Integrated Photonics from Visible to Mid‐Infrared Spectra

Buzaverov,

Baburin,

Sergeev

et al. 2024

Laser & Photonics Reviews

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Silicon nitride (Si3N4) photonic integrated circuits (PICs) are of great interest due to their extremely low propagation loss and higher integration capabilities. The number of applications based on the silicon nitride integrated photonics platform continues to grow, including the Internet of Things (IoT), artificial intelligence (AI), light detection and ranging (LiDAR), hybrid neuromorphic and quantum computing. It's potential for CMOS compatibility, as well as advances in heterogeneous integration with silicon‐on‐insulator, indium phosphate, and lithium niobate on insulator platforms, are leading to an advanced hybrid large‐scale PICs. Here, they review key trends in Si3N4 photonic integrated circuit technology and fill an information gap in the field of state‐of‐the‐art devices operating from the visible to the mid‐infrared spectrum. A comprehensive overview of its microfabrication process details (deposition, lithography, etching, etc.) is introduced. Finally, the limitations and challenges of silicon nitride photonics performance are pointed out in an ultra‐wideband, providing routes and prospects for its future scaling and optimization.

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Optical hydrogen sensing with high-Q guided-mode resonance of Al2O3/WO3/Pd nanostructure

Cited by 8 publications

References 54 publications

Permeable diffractive optical elements for real-time sensing of running fluids

Permeable diffractive optical elements for real-time sensing of running fluids

Noise Tolerant Photonic Bowtie Grating Environmental Sensor

Silicon Nitride Integrated Photonics from Visible to Mid‐Infrared Spectra

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