Enhancing CO2 photo-biochemical conversion in a newly-designed attached photobioreactor characterized by stacked horizontal planar waveguide modules

In the paper experiments and theory of biogas production using industrial waste from paper production as a co-substrate are described. The main aim of the experiments was to evaluate the sensitivity and applicability of the biochemical conversion using the anaerobic digestion of the mixed biomass in the pilot fermentor (5 m3), where the mesophillic temperature was maintained. It was in parallel operation with a large scale fermentor (100 m3). The research was carried out at the biogas plant in Kolíňany, which is a demonstration facility of the Slovak University of Agriculture in Nitra. The experiments proved that the waste arising from the paper production can be used in case of its appropriate dosing as an input substrate for biogas production, and thus it can improve the economic balance of the biogas plant.

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Excitation mode-dependent terahertz radiation generation from a sub-wavelength Si-SiO2-LiNbO3-polymer-Si planar waveguide

IEEE Transactions on Terahertz Science and Technology ◽

10.1109/tthz.2021.3063847 ◽

2021 ◽

pp. 1-1

Author(s):

Brett N Carnio ◽

Basem Shahriar ◽

Eric Hopmann ◽

Abdulhakem Y Elezzabi

Keyword(s):

Terahertz Radiation ◽

Planar Waveguide ◽

Excitation Mode ◽

Radiation Generation ◽

Sub Wavelength

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A Review on Improved Design Techniques for High Performance Planar Waveguide Slot Arrays

Electronics ◽

10.3390/electronics10111311 ◽

2021 ◽

Vol 10 (11) ◽

pp. 1311

Author(s):

Giovanni Andrea Casula ◽

Giuseppe Mazzarella ◽

Giorgio Montisci ◽

Giacomo Muntoni

Keyword(s):

Planar Waveguide ◽

High Performance ◽

Order Effects ◽

Waveguide Slot ◽

Waveguide Bends ◽

Radar Systems ◽

Slot Arrays ◽

Planar Array ◽

Improved Design ◽

Design Techniques

Planar waveguide slot arrays (WSAs) have been used since 1940 and are currently used as performing antennas for high frequencies, especially in applications such as communication and RADAR systems. We present in this work a review of the most typical waveguide slot array configurations proposed in the literature, describing their main limitations and drawbacks along with possible effective countermeasures. Our attention has been focused mainly on the improved available design techniques to obtain high performance WSAs. In particular, the addressed topics have been reported in the following. Partially filled WSAs, or WSAs covered with single or multilayer dielectric slabs, are discussed. The most prominent second-order effects in the planar array feeding network are introduced and accurately modeled. The attention is focused on the T-junction feeding the array, on the effect of interaction between each slot coupler of the feeding network and the radiating slots nearest to this coupler, and on the waveguide bends. All these effects can critically increase the first sidelobes if compared to the ideal case, causing a sensible worsening in the performance of the array.

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Fluorescence-based planar waveguide biosensors

10.1117/12.372900 ◽

1999 ◽

Cited By ~ 3

Author(s):

Gert L. Duveneck

Keyword(s):

Planar Waveguide

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Development of a Temperature-Controlled Optical Planar Waveguide Sensor with Lossy Mode Resonance for Refractive Index Measurement

Photonics ◽

10.3390/photonics8060199 ◽

2021 ◽

Vol 8 (6) ◽

pp. 199

Author(s):

Yu-Cheng Lin ◽

Liang-Yü Chen

Keyword(s):

Refractive Index ◽

Optical Fiber ◽

Temperature Control ◽

Planar Waveguide ◽

Metallic Oxide ◽

Refractive Index Measurement ◽

Index Measurement ◽

Temperature Controlled ◽

Optical Planar Waveguide ◽

Active Temperature

The generation of lossy mode resonances (LMR) with a metallic oxide film deposited on an optical fiber has attracted the attention of many applications. However, an LMR-based optical fiber sensor is frangible, and therefore it does not allow control of the temperature and is not suited to mass production. This paper aims to develop a temperature-controlled lossy mode resonance (TC-LMR) sensor on an optical planar waveguide with an active temperature control function in which an ITO film is not only used as the LMR resonance but also to provide the heating function to achieve the benefits of compact size and active temperature control. A simple flat model about the heat transfer mechanism is proposed to determine the heating time constant for the applied voltages. The TC-LMR sensor is evaluated experimentally for refractive index measurement using a glycerol solution. The heating temperature functions relative to the controlled voltages for water and glycerol are obtained to verify the performance of the TC-LMR sensor. The TC-LMR sensor is a valuable sensing device that can be used in clinical testing and point of care for programming heating with precise temperature control.

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