Consideration of the Role of Plasma in a Plasma-Coupled Selective Catalytic Reduction of Nitrogen Oxides with a Hydrocarbon Reducing Agent

Lee, Byeong-Ju; Kang, Ho-Chul; Jo, Jin Oh; Mok, Young Sun

doi:10.3390/catal7110325

Cited by 12 publications

(8 citation statements)

References 38 publications

(76 reference statements)

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“…14 In the plasma discharge zone, the oxidation of HCs is facilitated to form partially oxidized HCs at low temperature, which enhances the reduction of NO x . 15 Furthermore, O radicals, OH radicals, O 3 , and peroxyl radicals (RO 2 , HO 2 ), all of which are reactive chemical species, could be formed in the discharge zone. 16 In exhaust gas, most of the NO x exists in the form of NO, and the SCR of NO x would be promoted by increasing the ratio of NO 2 / NO x in the feed gas.…”

Section: Introductionmentioning

confidence: 99%

High-Throughput NO_x Removal by Two-Stage Plasma Honeycomb Monolith Catalyst

Nguyen

Matyakubov

Saud

et al. 2021

Environ. Sci. Technol.

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A two-stage plasma catalyst system for highthroughput NO x removal was investigated. Herein, the plasma stage involved the large-volume plasma discharge of humidified gas and was carried out in a sandwich-type honeycomb monolith reactor consisting of a commercial honeycomb catalyst (50 mm high; 93 mm in diameter) located between two parallel perforated disks that formed the electrodes. The results demonstrated that, in the plasma stage, the reduction of NO x did not occur at room temperature; instead, NO was only oxidized to NO 2 and n-heptane to oxygenated hydrocarbons. The oxidation of NO and n-heptane in the honeycomb plasma discharge state was largely affected by the humidity of the feed gas. Furthermore, the oxidation of NO to NO 2 occurs preferably to that of n-heptane with a tendency of the NO oxidation to decrease with increasing feed gas humidity. The reason is that the generation of O 3 decreases as the amount of water vapor in the feed gas increases. Compared to the catalyst alone, the two-stage plasma catalyst system increased NO x removal by 29% at a temperature of 200 °C and an energy density of 25 J/L.

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Section: Introductionmentioning

confidence: 99%

High-Throughput NO_x Removal by Two-Stage Plasma Honeycomb Monolith Catalyst

Nguyen

Matyakubov

Saud

et al. 2021

Environ. Sci. Technol.

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“…Plasma coupled with a catalyst, therefore, enables the removal of both NO x and soot at low operating temperatures. Moreover, enhanced NO x removal under fluctuating temperatures was also observed in the presence of plasma [47][48][49][50].…”

Section: Introductionmentioning

confidence: 83%

“…However, the efficiency of NO x removal was not satisfactory with 48 ppm naphthalene tantamount to a C/N ratio of 1.6 (the ratio of carbon concentration in the hydrocarbon to nitrogen concentration in NO x ). Previous reports indicated that n-alkane is an effective reducing agent for the HC-SCR process [48][49][50]. In general, dodecane (C 12 H 26 ) can represent diesel fuel.…”

Section: Removal Of No X and Soot Simulant By Scr Coupled With Plasmamentioning

confidence: 99%

Plasma-Assisted Selective Catalytic Reduction for Low-Temperature Removal of NOx and Soot Simulant

Nguyen

Heo

et al. 2019

Catalysts

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The challenge that needs to be overcome regarding the removal of nitrogen oxides (NOx) and soot from exhaust gases is the low activity of the selective catalytic reduction of NOx at temperatures fluctuating from 150 to 350 °C. The primary goal of this work was to enhance the conversion of NOx and soot simulant by employing a Ag/α-Al2O3 catalyst coupled with dielectric barrier discharge plasma. The results demonstrated that the use of a plasma-catalyst process at low operating temperatures increased the removal of both NOx and naphthalene (soot simulant). Moreover, the soot simulant functioned as a reducing agent for NOx removal, but with low NOx conversion. The high efficiency of NOx removal required the addition of hydrocarbon fuel. In summary, the combined use of the catalyst and plasma (specific input energy, SIE ≥ 60 J/L) solved the poor removal of NOx and soot at low operating temperatures or during temperature fluctuations in the range of 150–350 °C. Specifically, highly efficient naphthalene removal was achieved with low-temperature adsorption on the catalyst followed by the complete decomposition by the plasma-catalyst at 350 °C and SIE of 90 J/L.

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“…This treatment method can not only maintain the catalyst skeleton, remove organic impurities such as template, and prevent the sintering of metal clusters from becoming large, but also has a relatively short processing time compared to conventional roasting. Many experiments have shown that this plasma roasting can replace conventional high-temperature roasting [27,28,29]. …”

Section: Introductionmentioning

confidence: 99%

Application of Plasma Treatment in Preparation of Soybean Oil Factory Sludge Catalyst and Its Application in Selective Catalytic Oxidation (SCO) Denitration

Zhang

Yang

et al. 2018

Materials

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At present, the most commonly used denitration process is the selective catalytic reduction (SCR) method. However, in the SCR method, the service life of the catalyst is short, and the industrial operation cost is high. The selective catalytic oxidation absorption (SCO) method can be used in a low temperature environment, which greatly reduces energy consumption and cost. The C/N ratio of the sludge produced in the wastewater treatment process of the soybean oil plant used in this paper is 9.64, while the C/N ratio of the sludge produced by an urban sewage treatment plant is 10–20. This study shows that the smaller the C/N ratio, the better the denitration efficiency of the catalyst. Therefore, dried oil sludge is used as a catalyst carrier. The influence of different activation times, and LiOH concentrations, on catalyst activity were investigated in this paper. The denitration performance of catalysts prepared by different activation sequences was compared. The catalyst was characterized by Fourier Transform infrared spectroscopy (FTIR), X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), and scanning electron microscope (SEM). The experimental results showed that: (1) When the concentration of the LiOH solution used for activation is 15%, and the activation time is four hours, the denitration effect of the catalyst is the best; (2) the catalyst prepared by activation before plasma roasting has the best catalytic activity.

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Consideration of the Role of Plasma in a Plasma-Coupled Selective Catalytic Reduction of Nitrogen Oxides with a Hydrocarbon Reducing Agent

Cited by 12 publications

References 38 publications

High-Throughput NO_x Removal by Two-Stage Plasma Honeycomb Monolith Catalyst

High-Throughput NO_x Removal by Two-Stage Plasma Honeycomb Monolith Catalyst

Plasma-Assisted Selective Catalytic Reduction for Low-Temperature Removal of NOx and Soot Simulant

Application of Plasma Treatment in Preparation of Soybean Oil Factory Sludge Catalyst and Its Application in Selective Catalytic Oxidation (SCO) Denitration

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Consideration of the Role of Plasma in a Plasma-Coupled Selective Catalytic Reduction of Nitrogen Oxides with a Hydrocarbon Reducing Agent

Cited by 12 publications

References 38 publications

High-Throughput NOx Removal by Two-Stage Plasma Honeycomb Monolith Catalyst

High-Throughput NOx Removal by Two-Stage Plasma Honeycomb Monolith Catalyst

Plasma-Assisted Selective Catalytic Reduction for Low-Temperature Removal of NOx and Soot Simulant

Application of Plasma Treatment in Preparation of Soybean Oil Factory Sludge Catalyst and Its Application in Selective Catalytic Oxidation (SCO) Denitration

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Product

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About

High-Throughput NO_x Removal by Two-Stage Plasma Honeycomb Monolith Catalyst

High-Throughput NO_x Removal by Two-Stage Plasma Honeycomb Monolith Catalyst