Investigation of the PAH and Carbon Nanoparticles Formation Processes in the Ethylene Pyrolysis with the Tetrahydrofuran Addition Behind the Shock Waves

Q3 Mathematics

Herald of the Bauman Moscow State Technical University. Series Natural Sciences Pub Date : 2023-08-01 DOI:10.18698/1812-3368-2023-4-79-107

A.V. Drakon, A.V. Eremin, M.R. Korshunova, E.Yu. Mikheyeva

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Abstract

Currently, substances are being actively sought that could serve as the alternative fuel or fuel additive reducing formation and emission of the carbon nanoparticles. Here, processes of the polyaromatic hydrocarbons (precursors of the carbon condensed phase formation) and carbon black nanoparticles formation during the ethylene pyrolysis with addition of the tetrahydrofuran were studied by laser-induced fluorescence and laser extinction methods. Spectral dependences of laser-induced fluorescence of the polyaromatic hydrocarbons were obtained by laser-induced fluorescence at various temperatures and pyrolysis stages, and optical density of the reacting gas mixtures at wavelengths of 405 and 633 nm was obtained by laser extinction. Measurements were carried out on a shock tube behind the reflected shock waves in the temperature range of 1,695--2,500 K and pressure range of 2.7--4.1 atm. It is shown that during the ethylene pyrolysis with the tetrahydrofuran addition soot formation process is intensifying, and the temperature range of the carbon nanoparticles formation is expanding. Using the kinetic simulation, it was found that acceleration in the carbon nanoparticles formation was caused by formation of methyl radical and propylene in the tetrahydrofuran pyrolysis

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激波后四氢呋喃加成乙烯热解过程中多环芳烃和碳纳米颗粒形成过程的研究

目前，人们正在积极寻找可以作为替代燃料或燃料添加剂的物质，以减少碳纳米颗粒的形成和排放。本文采用激光诱导荧光法和激光消光法研究了四氢呋喃加入乙烯热解过程中多芳烃(碳凝聚相形成的前体)和炭黑纳米颗粒的形成过程。通过不同温度和热解阶段的激光诱导荧光获得了多芳烃激光诱导荧光的光谱依赖性，通过激光消光获得了反应气体混合物在405 nm和633 nm波长处的光密度。测量是在反射冲击波后面的激波管上进行的，温度范围为1695—2500 K，压力范围为2.7—4.1 atm。结果表明，在乙烯热解过程中，四氢呋喃的加入使烟尘的形成过程加剧，碳纳米颗粒的形成温度范围扩大。通过动力学模拟发现，四氢呋喃热解过程中甲基自由基和丙烯的生成加速了纳米碳颗粒的形成

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来源期刊

Herald of the Bauman Moscow State Technical University. Series Natural Sciences Mathematics-Mathematics (all)

CiteScore

1.10

自引率

0.00%

发文量

期刊介绍： The journal is aimed at publishing most significant results of fundamental and applied studies and developments performed at research and industrial institutions in the following trends (ASJC code): 2600 Mathematics 2200 Engineering 3100 Physics and Astronomy 1600 Chemistry 1700 Computer Science.