Modeling for plasma-enhanced catalytic reduction of nitrogen oxides

Tochikubo, Fumiyoshi

doi:10.1016/j.tsf.2009.07.169

Cited by 7 publications

(2 citation statements)

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“…Our present model, however, assumes spatially uniform discharge between the electrodes because the simulation of 2D or 3D filamentary discharges requires a very long computation time. [20][21][22] In the case of filamentary discharges, electron collision dissociation of molecules occurs only at the positions where filamentary discharge occurs. In other positions, the source gas passes through without being affected by electron collisions.…”

Section: Simulation Modulesmentioning

confidence: 99%

Effects of ambient air on the characteristics of an atmospheric-pressure plasma jet of a gas mixture of highly N₂-diluted O₂on a sliding substrate

Shirafuji

Sawada

2017

Jpn. J. Appl. Phys.

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We have performed numerical simulations of reaction kinetics and flow dynamics of an atmospheric-pressure plasma jet (APPJ) of a gas mixture of 99.9% N 2 and 0.1% O 2 in a two-dimensional flow channel with a height of 5 mm and investigated the effects of a sliding substrate and the substitution of the ambient gas. The sliding substrate in the flow channel produces the gas-drag effect, which results in not only the bending of the APPJ trajectory but also significant loss of atomic oxygen when the ambient gas is air. The flux of atomic oxygen integrated on the substrate is reduced to 19% of that integrated on the fixed substrate. We discuss the mechanisms of the reduction in the atomic oxygen flux through the analysis of spatial distributions of atomic oxygen loss reactions and show that the reduction in the atomic oxygen flux can be suppressed by substituting the ambient gas (air) with N 2 .

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Section: Simulation Modulesmentioning

confidence: 99%

Effects of ambient air on the characteristics of an atmospheric-pressure plasma jet of a gas mixture of highly N₂-diluted O₂on a sliding substrate

Shirafuji

Sawada

2017

Jpn. J. Appl. Phys.

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“…Similar research was conducted by Li and Dhali 47) and Steinle et al 48) In a more application-oriented study, singlestreamer propagation in DBD in a N 2 /O 2 /NO mixture was calculated by two-dimensional fluid model and reaction processes for NO oxidation was traced aiming for plasmaassisted selective catalytic reduction of NO 2 . 49,50) Simulation of APNP-Js has also been performed by many researchers. [51][52][53][54][55][56] The purpose of this paper is to review progress in the simulation of atmospheric-pressure non-equilibrium plasmas, especially streamer discharges and APGDs, using the fluid approximation model over the last two decades and the current understanding of the discharge evolution process.…”

Section: Introductionmentioning

confidence: 99%

Review of numerical simulation of atmospheric-pressure non-equilibrium plasmas: streamer discharges and glow discharges

Tochikubo

Komuro

2021

Jpn. J. Appl. Phys.

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Over the past two decades, research and development using various atmospheric-pressure non-equilibrium plasmas has been conducted energetically for materials synthesis, surface treatment, environmental and energy applications, plasma medicine, plasma agriculture, and other applications. Precise understanding of the physics and chemistry of atmospheric-pressure non-equilibrium plasmas is indispensable for further development of these applications. In this paper, we review progress in the simulation of atmospheric-pressure non-equilibrium plasmas, especially streamer discharges and atmospheric-pressure glow discharges as the most fundamental discharge forms, using the fluid approximation model over the last two decades, and the current understanding of the discharge evolution process. In addition, we discuss recent findings on plasma–liquid interactions obtained from simulations of atmospheric-pressure plasmas in contact with liquids.

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Plasma Catalysis Modeling

Bogaerts

Neyts

2019

Plasma Catalysis

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Modeling for plasma-enhanced catalytic reduction of nitrogen oxides

Cited by 7 publications

References 4 publications

Effects of ambient air on the characteristics of an atmospheric-pressure plasma jet of a gas mixture of highly N₂-diluted O₂on a sliding substrate

Effects of ambient air on the characteristics of an atmospheric-pressure plasma jet of a gas mixture of highly N₂-diluted O₂on a sliding substrate

Review of numerical simulation of atmospheric-pressure non-equilibrium plasmas: streamer discharges and glow discharges

Plasma Catalysis Modeling

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Modeling for plasma-enhanced catalytic reduction of nitrogen oxides

Cited by 7 publications

References 4 publications

Effects of ambient air on the characteristics of an atmospheric-pressure plasma jet of a gas mixture of highly N2-diluted O2on a sliding substrate

Effects of ambient air on the characteristics of an atmospheric-pressure plasma jet of a gas mixture of highly N2-diluted O2on a sliding substrate

Review of numerical simulation of atmospheric-pressure non-equilibrium plasmas: streamer discharges and glow discharges

Plasma Catalysis Modeling

Contact Info

Product

Resources

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Effects of ambient air on the characteristics of an atmospheric-pressure plasma jet of a gas mixture of highly N₂-diluted O₂on a sliding substrate

Effects of ambient air on the characteristics of an atmospheric-pressure plasma jet of a gas mixture of highly N₂-diluted O₂on a sliding substrate