Kinetic roles of vibrational excitation in RF plasma assisted methane pyrolysis

能源化学(英文版) ›› 2019, Vol. 39 ›› Issue (12): 188-197.

Kinetic roles of vibrational excitation in RF plasma assisted methane pyrolysis

Jintao Sun, Qi Chen

School of Mechanical, Electronic and Control Engineering, Beijing Jiaotong University, Beijing 100044, China

收稿日期:2018-12-08 修回日期:2019-01-25 出版日期:2019-12-15 发布日期:2020-12-18
通讯作者: Qi Chen, qchen@bjtu.edu.cn
基金资助:
This work was supported by the National Natural Science Foundation of China (Grant No. 21676024), the Beijing Natural Science Foundation (Grant No. 3182029) and the Fundamental Research Funds for the Central Universities (2018YJS141).

Kinetic roles of vibrational excitation in RF plasma assisted methane pyrolysis

Jintao Sun, Qi Chen

School of Mechanical, Electronic and Control Engineering, Beijing Jiaotong University, Beijing 100044, China

Received:2018-12-08 Revised:2019-01-25 Online:2019-12-15 Published:2020-12-18
Contact: Qi Chen, qchen@bjtu.edu.cn
Supported by:
This work was supported by the National Natural Science Foundation of China (Grant No. 21676024), the Beijing Natural Science Foundation (Grant No. 3182029) and the Fundamental Research Funds for the Central Universities (2018YJS141).

摘要/Abstract

摘要： A combined experimental and simulational work was carried out in this paper to investigate the kinetic effects of non-equilibrium excitation by direct electron impact on low temperature pyrolysis of CH₄ in a RF dielectric barrier discharge. Special attention was placed on the vibrational chemistry of CH₄ and some other important products including H₂, C₂H₂, C₂H₄, C₂H₆ and C₃H₈ largely produced in CH₄/He discharge under an intermediate reduced electric field ranging 51-80 Td. A detailed kinetic mechanism incorporating a set of electron impact reactions, electron-ion recombination reactions, negative ions attachment reactions, charge exchange reactions, reactions involving vibrationally excited molecules and the relaxation process of vibrationally excited species was assembled and experimentally validated. The modeling results showed a reasonable agreement with the experimentally measured results in terms of CH₄ conversion and products production including C₂ hydrocarbons and hydrogen. A linear increasing trend of methane conversion with increasing plasma power input was discovered, which suggested a strong dependence of molecular excitation on energy input. Both the CH₄/He mole ratio and the reactor temperature play significant roles in CH₄ conversion and major products production. The experimental results showed that the selectivity of value-added products C₂H₄ and H₂ keeps essentially unchanged with increasing energy input, mostly because the contribution CH₄ ionization and He excitation effectively compete with vibrational excitation and dissociation of CH₄ molecule with the E/N value increasing. The calculated results showed that the typical relaxation time of vibrational states is comparable to the gas-kinetics time in a CH₄/He discharge mixture, thus the vibrationally excited molecules can significantly accelerate chemical reactions through an effective decrease of activation energy. The path flux analysis revealed that the vibrationally excited molecules CH₄(v) and H₂(v) enhanced chain propagation reactions, such as CH₄(v)+H→CH₃+H₂, CH₄(v)+CH→C₂H₄+H, and H₂(v)+C→CH+H, further stimulating the production of active radicals and final products. Specifically, H₂(v)+C→CH+H was responsible for 7.9% of CH radical formation and CH₄(v)+CH→C₂H₄+H accounted for 31.4% of total C₂H₄ production. This kinetic study provides new sights in demonstrating the contribution of vibrationally excited molecules in RF plasma assisted methane pyrolysis.

关键词: Non-equilibrium plasma, Methane pyrolysis, Vibrational excitation, Path flux analysis, Sensitivity analysis

Abstract: A combined experimental and simulational work was carried out in this paper to investigate the kinetic effects of non-equilibrium excitation by direct electron impact on low temperature pyrolysis of CH₄ in a RF dielectric barrier discharge. Special attention was placed on the vibrational chemistry of CH₄ and some other important products including H₂, C₂H₂, C₂H₄, C₂H₆ and C₃H₈ largely produced in CH₄/He discharge under an intermediate reduced electric field ranging 51-80 Td. A detailed kinetic mechanism incorporating a set of electron impact reactions, electron-ion recombination reactions, negative ions attachment reactions, charge exchange reactions, reactions involving vibrationally excited molecules and the relaxation process of vibrationally excited species was assembled and experimentally validated. The modeling results showed a reasonable agreement with the experimentally measured results in terms of CH₄ conversion and products production including C₂ hydrocarbons and hydrogen. A linear increasing trend of methane conversion with increasing plasma power input was discovered, which suggested a strong dependence of molecular excitation on energy input. Both the CH₄/He mole ratio and the reactor temperature play significant roles in CH₄ conversion and major products production. The experimental results showed that the selectivity of value-added products C₂H₄ and H₂ keeps essentially unchanged with increasing energy input, mostly because the contribution CH₄ ionization and He excitation effectively compete with vibrational excitation and dissociation of CH₄ molecule with the E/N value increasing. The calculated results showed that the typical relaxation time of vibrational states is comparable to the gas-kinetics time in a CH₄/He discharge mixture, thus the vibrationally excited molecules can significantly accelerate chemical reactions through an effective decrease of activation energy. The path flux analysis revealed that the vibrationally excited molecules CH₄(v) and H₂(v) enhanced chain propagation reactions, such as CH₄(v)+H→CH₃+H₂, CH₄(v)+CH→C₂H₄+H, and H₂(v)+C→CH+H, further stimulating the production of active radicals and final products. Specifically, H₂(v)+C→CH+H was responsible for 7.9% of CH radical formation and CH₄(v)+CH→C₂H₄+H accounted for 31.4% of total C₂H₄ production. This kinetic study provides new sights in demonstrating the contribution of vibrationally excited molecules in RF plasma assisted methane pyrolysis.

Key words: Non-equilibrium plasma, Methane pyrolysis, Vibrational excitation, Path flux analysis, Sensitivity analysis

Jintao Sun, Qi Chen. Kinetic roles of vibrational excitation in RF plasma assisted methane pyrolysis[J]. 能源化学(英文版), 2019, 39(12): 188-197.

Jintao Sun, Qi Chen. Kinetic roles of vibrational excitation in RF plasma assisted methane pyrolysis[J]. Journal of Energy Chemistry, 2019, 39(12): 188-197.

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Kinetic roles of vibrational excitation in RF plasma assisted methane pyrolysis

Kinetic roles of vibrational excitation in RF plasma assisted methane pyrolysis

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