利用 CO2/Ar 气液 DBD 等离子体去除 4,4'- 磺酰双的机理研究

Pub Date : 2024-10-01 DOI:10.1088/2058-6272/ad5118
Guangjia WANG, Shidong FANG, Baoguo LIN, Chengzhu ZHU, Jie SHEN
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引用次数: 0

摘要

本研究采用单介质阻挡放电(DBD)同轴反应器,以温室气体(CO2)和氩气为载气,降解水中的 4,4'-磺酰双(TBBPS)。研究的重点是放电等离子体过程中 CO2 的转化、活性物种的形成、气液传质机理以及 TBBPS 的降解机理。在等离子体放电过程中,随着 CO2/Ar 比率的降低,Ar、CO2 和受激反应物种的发射光谱强度增强。这种增强促进了 CO2 的碰撞和解离,从而产生了一系列化学反应,促进了 -OH、1O2、H2O2 和 O3 等反应物的产生。这些活性物质引发了与 TBBPS 的一系列反应。结果表明,在气体流速为 240 mL/min 和 CO2/Ar 比率为 1:5 的条件下,CO2 转化率(17.76%)和 TBBPS 降解率(94.24%)均达到最高。通过使用液相色谱-质谱技术测定处理液中反应物的种类和含量以及分析中间产物,阐明了降解机理。这项研究为通过介质阻挡放电等离子体技术利用二氧化碳和控制水污染提供了新的见解。
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Mechanistic study on 4, 4'-sulfonylbis removal with CO2/Ar gas-liquid DBD plasma
In this study, a single dielectric barrier discharge (DBD) coaxial reactor was used to degrade 4, 4'-sulfonylbis (TBBPS) in water using greenhouse gas (CO2) and argon as the carrier gases. The investigation focused on CO2 conversion, reactive species formation, gas-liquid mass transfer mechanism, and degradation mechanism of TBBPS during the discharge plasma process. With the decrease of CO2/Ar ratio in the process of plasma discharge, the emission spectrum intensity of Ar, CO2 and excited reactive species was enhanced. This increase promoted collision and dissociation of CO2, resulting in a series of chemical reactions that improved the production of reactive species such as ·OH, 1O2, H2O2 and O3. These reactive species initiated a sequence of reactions with TBBPS. Results indicated that at a gas flow rate of 240 mL/min with a CO2/Ar ratio of 1:5, both the highest CO2 conversion rate (17.76%) and TBBPS degradation rate (94.24%) were achieved. The degradation mechanism was elucidated by determining types and contents of reactive species present in treatment liquid along with analysis of intermediate products using liquid chromatography-mass spectrometry techniques. This research provides novel insights into carbon dioxide utilization and water pollution control through dielectric barrier discharge plasma technology.
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