Silicon photonics waveguide array sensor for selective detection of VOCs at room temperature

Janeiro, Ricardo; Flores, Raquel; Viegas, Jaime

doi:10.1038/s41598-019-52264-9

Cited by 19 publications

(16 citation statements)

References 26 publications

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“…Equation (5) shows that the heat generation at each instant is counteracted by the heat flowing out of the warming cavity, represented by the term H (t ). In this section, the heat dissipation dynamics, governed by H (t ), are discussed in detail.…”

Section: Thermal Dynamics Of the Single Mode Cavitymentioning

confidence: 99%

“…The level of high sophistication in silicon microfabrication technology, and the possibility to merge the already existing electronics to photonics on the same high performance complementary metal-oxide semiconductor (CMOS) silicon chip [1], have generated recent considerable interest in silicon photonics. Silicon is becoming the leading platform for the creation of large-scale photonic integrated circuits for key enabling applications in various technology sectors, such as high-bandwidth optical interconnects and midinfrared optical sensing [2][3][4][5], offering low absorption, a high refractive index contrast and scalable mass manufacture. Recent advances in light confinement at the wavelength scale are leading to smaller and smaller high-performance resonators fabricated on silicon-on-insulator platforms.…”

Section: Introductionmentioning

confidence: 99%

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Model of thermo-optic nonlinear dynamics of photonic crystal cavities

Iadanza

Clementi

et al. 2020

Phys. Rev. B

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The wavelength scale confinement of light offered by photonic crystal (PhC) cavities is one of the fundamental features on which many important on-chip photonic components are based, opening silicon photonics to a wide range of applications from telecommunications to sensing. This trapping of light in a small space also greatly enhances optical nonlinearities and many potential applications build on these enhanced light-matter interactions. In order to use PhCs effectively for this purpose it is necessary to fully understand the nonlinear dynamics underlying PhC resonators. In this work, we derive a first principles thermal model outlining the nonlinear dynamics of optically pumped silicon two-dimensional (2D) PhC cavities by calculating the temperature distribution in the system in both time and space. We demonstrate that our model matches experimental results well and use it to describe the behavior of different types of PhC cavity designs. Thus, we demonstrate the model's capability to predict thermal nonlinearities of arbitrary 2D PhC microcavities in any material, only by substituting the appropriate physical constants. This renders the model critical for the development of nonlinear optical devices prior to fabrication and characterization.

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Section: Thermal Dynamics Of the Single Mode Cavitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Model of thermo-optic nonlinear dynamics of photonic crystal cavities

Iadanza

Clementi

et al. 2020

Phys. Rev. B

View full text Add to dashboard Cite

show abstract

“…Si photonic sensors have been extensively explored to be employed in important areas like fundamental medical research and diagnosis, bioterrorism detection, smart home healthcare diagnostics, and gas detecting [33][34][35]. High sensitivity is desired in these devices, which robustly relies on device size, optical loss, light polarization, and light-matter interaction.…”

Section: Silicon µ-Rr Biosensorsmentioning

confidence: 99%

State-of-the-Art Optical Devices for Biomedical Sensing Applications—A Review

et al. 2021

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Optical sensors for biomedical applications have gained prominence in recent decades due to their compact size, high sensitivity, reliability, portability, and low cost. In this review, we summarized and discussed a few selected techniques and corresponding technological platforms enabling the manufacturing of optical biomedical sensors of different types. We discussed integrated optical biosensors, vertical grating couplers, plasmonic sensors, surface plasmon resonance optical fiber biosensors, and metasurface biosensors, Photonic crystal-based biosensors, thin metal films biosensors, and fiber Bragg grating biosensors as the most representative cases. All of these might enable the identification of symptoms of deadly illnesses in their early stages; thus, potentially saving a patient’s life. The aim of this paper was not to render a definitive judgment in favor of one sensor technology over another. We presented the pros and cons of all the major sensor systems enabling the readers to choose the solution tailored to their needs and demands.

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“…optics [12], [13]. Among them, optical fiber sensors based on intermodal interference have become one of the major optical sensing techniques, which can sense the changes of external refractive index, temperature, humidity, strain, displacement, pH value, and other parameters in time by converting these changes into optical signals such as interference peak wavelength [14]- [19].…”

Section: Introductionmentioning

confidence: 99%

Temperature-Insensitive Label-Free Sensors for Human IgG Based on S-Tapered Optical Fiber Sensors

et al. 2021

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We demonstrate a temperature-insensitive and high-sensitive label-free biosensor for low-concentration Human IgG detection based on S-tapered optical fiber (STF). The sensor is sensitive to local refractive index changes and has high robustness against temperature noise without a temperature control system. The temperature sensitivity of the sensor is −0.02nm/ • C in the range of 25 • C-45 • C. Within 15 minutes at room temperature, the average drift of the center wavelength is 0.04 nm. The calibration experiments demonstrate that STFs for liquid achieved a sensing precision of 0.04 nm and a sensitivity of 538.62 nm/RIU. The STFs are applied for the concentration measurement of multiple diluted ex vivo IgG biomolecule solutions. The results showed that STFs were reliable for low-concentration IgG detection and its lower limit of measurement was demonstrated as 28 ng/ml. With the advantages of temperatureinsensitive, compact size, low cost, high precision, real-time detection, fast response, good specificity, this STF sensors are promising for the antigen detection applications.INDEX TERMS Human IgG, high precision, S-tapered fiber biosensor, temperature-insensitive.

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Silicon photonics waveguide array sensor for selective detection of VOCs at room temperature

Cited by 19 publications

References 26 publications

Model of thermo-optic nonlinear dynamics of photonic crystal cavities

Model of thermo-optic nonlinear dynamics of photonic crystal cavities

State-of-the-Art Optical Devices for Biomedical Sensing Applications—A Review

Temperature-Insensitive Label-Free Sensors for Human IgG Based on S-Tapered Optical Fiber Sensors

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