Photodetector based on Vernier-Enhanced Fabry-Perot Interferometers with a Photo-Thermal Coating

Chen, George G.; Wu, Xuan; Liu, Xiaokong; Lancaster, David G.; Monro, Tanya M.; Xu, Haolan

doi:10.1038/srep41895

Cited by 5 publications

(3 citation statements)

References 36 publications

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“…Such sensors [4]- [8] relying on various types of reflectometry are amongst the most commercially successful optical fiber-based sensors, alongside fiber Bragg gratings [9], fiber-optic gyroscopes [10] and other single-mode/multimode fiber-based sensors [11], [12]. It is well known that fiber-optic sensors are immune to electromagnetic interference [13], and are widely used to monitor spatially resolved temperature [5], strain [6], pressure [7] and vibrations [8] for structural-health monitoring of buildings, mines and oilrigs.…”

Section: Introductionmentioning

confidence: 99%

Short-Range Non-Bending Fully Distributed Water/Humidity Sensors

Chen

Schartner

et al. 2019

J. Lightwave Technol.

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Existing sensing technologies lack the ability to spatially resolve multiple sources of water or humidity without relying on the deployment of numerous inline sensors. A fully distributed approach has the potential to unlock a diverse range of applications, such as humidity mapping and liquid-depth measurements. We have explored a new direction toward what is, to the best of our knowledge, the first non-bending fully distributed water/humidity sensors. This new class of sensors was made possible from the first combination of small-core exposed-core fiber, a hydrophilic polyelectrolyte multilayer coating, and coherent optical frequency-domain reflectometry. Their non-bending nature enables deployment in a wider range of environments compared to the bending type based on water-induced fiber bending. The sensing mechanism involves monitoring back-reflected optical signals Manuscript

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Section: Introductionmentioning

confidence: 99%

Short-Range Non-Bending Fully Distributed Water/Humidity Sensors

Chen

Schartner

et al. 2019

J. Lightwave Technol.

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“…Depending on the desired spectral sensitivity, different physical principles should be considered. Among the sensors using semiconductors as active materials, this study highlights those working directly from [1,2,3,4]:Photoelectric or photovoltaic effects, where photons have energies over the semiconductor band gap;Thermal-based absorption sensors, where the photon energies require the generation of mid-gap states to provide energy to the phonon bath.…”

Section: Introductionmentioning

confidence: 99%

Thermoelectric Photosensor Based on Ultrathin Single-Crystalline Si Films †

Dalkiranis

Ferrando-Villalba

Lopeandía

et al. 2019

Sensors

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Ultrathin Si films have a reduced thermal conductivity in comparison to Si bulk due to phonon scattering at the surfaces. Furthermore, the small thickness guarantees a reduced thermal mass (in the µJ/K range), which opens up the possibility of developing thermal sensors with a high sensitivity. Based on these premises, a thermoelectric (TE) microsensor based on ultrathin suspended Si films was developed and used as a thermal photosensor. The photoresponse of the device was evaluated with an argon laser (λ = 457 nm) with a variable power ranging from 0 to 10 mW in air at atmospheric pressure, with laser diodes at 406 nm, 520 nm and 638 nm wavelengths, and fixed powers in high vacuum conditions. The responsivity per unit area, response time (τ) and detectivity (D*) of the device were determined in air at ambient pressure, being 2.6 × 107 V/Wm2, ~4.3 ms and 2.86 × 10 7 c m H z ( 1 / 2 ) W − 1 , respectively. Temperature differences up to 30 K between the central hot region and the Si frame were achieved during open-circuit voltage measurements, with and without laser diodes. During illumination, the photogeneration of carriers caused a slight reduction of the Seebeck coefficient, which did not significantly change the sensitivity of the device. Moreover, the measurements performed with light beam chopped at different frequencies evidenced the quick response of the device. The temperature gradients applied to the thermoelectric Si legs were corrected using finite element modeling (FEM) due to the non-flat temperature profile generated during the experiments.

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“…Typically, the main interest is the monitoring of hot spots in the power line, to prevent failures related to high-temperature degradation in the conductors. In applications like Dynamic Line Ratings (DLR) forecasting, it was reported that solar radiation can considerably increase the temperature of the conductor in low wind speed conditions, becoming a significant limiting factor [3]. In this scenario it was also reported that the solar radiation should be dynamically and continuously monitored along the conductor, since a single-point measurement of effective incident radiation would not be sufficient to compute the global combined effect of solar irradiance along the whole span.…”

Section: Introductionmentioning

confidence: 99%