Jyun-Yu Lin scite author profile

Jyun-Yu Lin

2Publications

29Citation Statements Received

175Citation Statements Given

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155

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National Chung Cheng University

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Analysis of ozone generation in a planar atmospheric pressure air dielectric barrier discharge reactor

Lin

Liao

Lin

et al. 2023

Plasma Sources Sci. Technol.

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This work investigates O3 production in a planar atmospheric pressure air dielectric barrier discharge reactor numerically and experimentally. The surface temperature of the reactor is measured by an infrared (IR) thermal imager, and the O3 densities of cases in the reactive zone are measured by ultraviolet absorption spectroscopy. The 1.5D plasma fluid model (PFM) with transverse convection is employed to capture the average properties of a single microdischarge (MD) generated in the reactor and is integrated with the 3D gas flow model for modeling species densities in the reactor. The simulated temperature distribution of the reactor surface is validated by that measured and the simulated O3 densities agree with those measured at different locations and flow rates. In the 1.5D PFM, the simulated results show that the O3 molecules produced in the case of 4 SLM are much more than those produced in the case of 1 SLM though the O atoms produced in the case of 1 SLM are around 20 % more than those produced in the case of 4 SLM. In the case of 1 SLM, more than 48% of O3 molecular generated are destructed, while only around 14% of O3 molecules are destructed in the case of 4 SLM. The analysis shows that around 73% of O atoms generated in the 1.5D PFM are consumed in the formation of O3 molecules in the case of 4 SLM, while only 18% of O atoms generated in the case of 1 SLM are consumed in the formation of O3 molecules. The overall O3 yield efficiency reaches 97 g/kWh with the O3 concentration increasing to 2700 ppm in the case of 4 SLM, while the O3 yield efficiency decreases to 10 g/kWh and O3 concentration drops to 1400 ppm in the case of 1 SLM.

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Characterization of OH species in kHz He/H₂O atmospheric pressure dielectric barrier discharges

Lin¹,

Huang²,

Chen³

et al. 2022

Plasma Sources Sci. Technol.

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This work investigates experimentally and numerically the chemical kinetics of OH species generated in kHz helium atmospheric-pressure dielectric barrier discharges with different H2O concentrations. The OH densities of cases are determined from measurements of the ultraviolet absorption spectroscopy (UVAS) system with transition parameters evaluated by LIFBASE. The 1D plasma fluid model (PFM) with compiled chemistry including the formation of charged cluster ions to capture the discharge dynamics for analyzing mechanisms of OH species properly. The simulated current densities of cases with 0.8% and 2.0% H2O concentrations increase from 29 to 51 A m-2, agreeing with experimental measurements. The simulated OH density increases from 1.5×10^19 m^-3 to 2.0×10^19 m^-3 as the H2O concentration increases from 0.4% to 2.0%, agreeing with OH densities interpreted from the UVAS system for cases with various H2O concentrations. The simulated results reveal that the electron and H2O+ are essential species for OH production through dissociative reactions (e + H2O -> e + OH + H) and (H2O+ + H2O ->H+(H2O) + OH) contributing to 61% and 23% of OH production, respectively. It is observed that the OH self-recombination reaction (OH + OH + He → H2O2 + He) contributes to 32% of OH consumption as the dominant reaction. Moreover, the stepwise recombination reactions (OH + H2O2 → H2O + HO2 and OH + HO2 → O2 + H2O) contribute to the overall 27% of OH consumption. As the essential species contributing to the OH production and consumption, a detailed analysis of electron and H species is conducted. The high average reaction rates of dissociative attachment reactions consume most of the electrons after the breakdown, which leads to the variation of discharge current density. The saturation of OH species is attributed to the transition of electron chemical kinetics and the recombination reactions of OH species.

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Jyun-Yu Lin

Analysis of ozone generation in a planar atmospheric pressure air dielectric barrier discharge reactor

Characterization of OH species in kHz He/H₂O atmospheric pressure dielectric barrier discharges

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Jyun-Yu Lin

Analysis of ozone generation in a planar atmospheric pressure air dielectric barrier discharge reactor

Characterization of OH species in kHz He/H2O atmospheric pressure dielectric barrier discharges

Contact Info

Product

Resources

About

Characterization of OH species in kHz He/H₂O atmospheric pressure dielectric barrier discharges