王德真

个人信息Personal Information

教授

博士生导师

硕士生导师

任职 : 《Plasma Science and Technology》学术期刊编委

性别:男

毕业院校:大连工学院

学位:硕士

所在单位:物理学院

学科:等离子体物理

办公地点:主楼东侧楼(物理系楼)304室

联系方式:0411-84707981

电子邮箱:wangdez@dlut.edu.cn

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The effect of hydrogen peroxide concentration on the partial oxidation of methane to methanol in an atmospheric dielectric barrier discharge

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论文类型:期刊论文

发表时间:2018-12-01

发表刊物:AIP ADVANCES

收录刊物:SCIE、Scopus

卷号:8

期号:12

ISSN号:2158-3226

关键字:Atmospheric chemistry; Dielectric devices; Dielectric materials; Flow control; Hydrogen peroxide; Methane; Methanol; Partial discharges; Peroxides; Synthesis (chemical); Synthesis gas manufacture, Atmospheric dielectric barrier discharge; Conversion of methanes; Electron impact dissociation; Hydrogen peroxide concentration; Hydrogen peroxide vapors; Nonequilibrium plasmas; Partial oxidation of methane; Spatial and temporal distribution, Oxidation

摘要:It was proved that atmospheric non-equilibrium plasma can be deemed as "reaction carrier", and is an effective method of partial oxidation of methane to methanol and other higher hydrocarbons. In this paper, hydrogen peroxide vapor is selected as oxygen-containing oxidizer and used to activate and convert methane into methanol in an atmospheric dielectric barrier discharge. A detailed axisymmetric 2D fluid model in CH4/H2O/H2O2 gas mixture is developed, with an emphasis on gas-phase plasma chemistry for partial oxidation of methane and methanol formation. Especially, the effect of hydrogen peroxide concentration on the conversion of methane to methanol is studied. The spatial and temporal distributions of various plasma species are shown as a function of hydrogen peroxide concentration. In addition, the main plasma species and reaction pathways governing the production and loss of CH3OH and OH are determined. It is shown that the increasing hydrogen peroxide concentration results in increase of OH and CH3OH production. Hydroxyl appears to play a significant role during the process of methanol synthesis, which is primarily produced by electron-impact dissociation of H2O2 and H2O molecules. (C) 2018 Author(s).