磁场增强介质阻挡放电CO<sub>2</sub>分解反应研究

doi:10.19595/j.cnki.1000-6753.tces.241853

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摘要大气压低温等离子体可以在常温常压条件下转化CO₂,实现环境保护并促进其转化为高价值化学品和燃料的目标。目前,介质阻挡放电（DBD）在CO₂转化方面备受关注,但其反应性能仍不理想。前期研究发现在DBD外施加磁场可以扩大DBD的放电区域,提高放电强度和电子密度,为提高CO₂转化性能提供了新途径。该文将外部磁场作用于同轴DBD用于CO₂直接分解的反应过程,研究外加磁场和反应参数对电气特性和反应性能的影响,旨在优化反应参数,提高反应性能。研究结果表明,提高电压幅值能够增强DBD放电强度,提升放电功率,产生更多活性粒子,从而提高CO₂转化率,但是会降低反应过程的能量效率。外部磁场作用能够进一步增强反应区域放电强度,促进CO₂分子激发解离过程的进行,从而克服部分能量损耗带来的不利影响,同时提高CO₂转化率、CO产率和能量效率。在外部磁场作用下,当电压幅值为24 kV时,CO₂转化率和CO产率最高,分别为12.4%和10.8%;而当电压幅值为18 kV时,能量效率最高为0.101 mmol/kJ,与未添加外部磁场时相比提高了6.4%。

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关键词 ：外部磁场, 介质阻挡放电, CO₂直接分解, 放电特性, 能量效率

Abstract：Direct CO₂ decomposition is a typical form to convert CO₂ into valuable chemical feedstocks and fuels. However, stringent reaction conditions are required in the conventional methods due to the intrinsic thermal stability of CO₂, which frequently result in suboptimal conversion and energy efficiencies. Low- temperature plasma technology (e.g., dielectric barrier discharge, DBD) offers a highly reactive environment for the activation and conversion of CO₂. CO₂ decomposition in DBD has been a hot topic, but its reaction performance is still not satisfactory. Introducing an external magnetic field into DBD can enhance discharge intensity, and consequently improve the performance for practical applications, which presents an innovative approach to improve CO₂ decomposition performance. Nonetheless, there is limited research on the effects of magnetic fields on the discharge characteristics of DBD and the corresponding CO₂ decomposition performance. The optimization of reaction parameters has yet to be clearly established, and underlying mechanisms have not been deeply understood. Herein, a comprehensive investigation has been performed on CO₂ decomposition in DBD enhanced by magnetic field.
The DBD reactor comprises the stainless steel inner rod and outer mesh electrodes, the NdFeB ring magnet, and the quartz dielectric tube. It is powered by a nanosecond pulsed power supply. The outer electrode is grounded after connected to a reference capacitor. Voltage and current measurements are obtained using a Tektronix high voltage probe, a Pin-tech voltage probe and a Pearson current coil, respectively. All signals are recorded using a Tektronix digital oscilloscope. Electrical characteristics are derived from voltage-current waveform analysis and the equivalent circuit model of DBD. An Andor spectrometer has been employed to identify the type and intensity of reactive species within the discharge space. Additionally, a Fotric thermal imaging device has been utilized to quantify temperature variations outside the reactor during discharge. The discharge characteristics has been discussed based on the results of electrical, optical and temperature characteristics. A PANNA gas chromatography has been utilized to analyze the gaseous components before and after the reaction. Reaction performance has been evaluated based on the conversion of CO₂ to CO and the overall process energy efficiency.
The following conclusions can be drawn from the study: (1) In the coaxial DBD system for the direct CO₂ decomposition, increasing the voltage amplitude results in a significant enhancement in discharge power. Introducing a magnetic field leads to further improvements in total power and energy utilization efficiency of the power supply. In the presence of a magnetic field, the peak value of the gap voltage and the energy utilization efficiency have been achieved at the voltage amplitude of 24 kV. (2) The presence of a magnetic field enhances the discharge intensity and promote the production of energetic electrons and other reactive species, which increases their possibility of collisions with CO₂ molecules, leading to the increase in both CO₂ conversion and CO yield. Introducing the magnetic field leads to the largest enhancement of 14.9% for CO₂ conversion when the voltage amplitude is 22 kV, while the largest enhancement for CO yield (11.9%) at the voltage amplitude of 20 kV. (3) The positive influence of magnetic field on CO₂ decomposition surpasses the negative influence of the resulted heat loss, which promotes the overall energy efficiency while increasing CO₂ conversion. The maximum energy efficiency of 0.101 mmol/kJ is achieved at an input voltage amplitude of 18 kV, which is increased by 6.4% compared to that obtained in the absence of a magnetic field. Further enhancement in the process energy is expected to be achieved by the optimization of the operating parameters and the development of suitable catalysts.

Key words： External magnetic field dielectric barrier discharge direct CO₂ decomposition discharge characteristics energy efficiency

收稿日期: 2024-10-21

PACS:

TM85

基金资助:国家自然科学基金面上项目资助（52177149）

通讯作者: 梅丹华男,1985年生,教授,硕士生导师,研究方向为高电压与气体放电等离子体技术及其能源环境应用。E-mail: danhuam@126.com

作者简介: 吕锡昂男,1998年生,硕士研究生,研究方向为大气压低温等离子体特性诊断及能源转化应用。E-mail: lvjojo589426@163.com

引用本文:

吕锡昂, 马添翼, 梅丹华, 陈慧敏, 方志. 磁场增强介质阻挡放电CO₂分解反应研究[J]. 电工技术学报, 2025, 40(21): 6832-6843. Lü Xi'ang, Ma Tianyi, Mei Danhua, Chen Huimin, Fang Zhi. CO₂ Decomposition in Dielectric Barrier Discharge Enhanced by Magnetic Field. Transactions of China Electrotechnical Society, 2025, 40(21): 6832-6843.

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