$$\hbox {CO}_2$$ / $$\hbox {CH}_4$$ Glow Discharge Plasma: Part I—Experimental and Numerical Study of the Reaction Pathways

Abstract

A fundamental study of \(\hbox {CO}_2\)/\(\hbox {CH}_4\) plasma is performed in a glow discharge at a few Torr. Experimental and numerical results are compared to identify the main reaction pathways. OES-based techniques and FTIR (Fourier Transform Infrared) spectroscopy are used to determine molecules densities and gas temperature. Several conditions of pressure, initial mixture and residence time are measured. The main dissociation products are found to be CO and \(\hbox {H}_2\). The LoKI simulation tool was used to build a simplified kinetic scheme to limit the uncertainties on rate coefficients, but sufficient to reproduce the experimental data. To this aim, only molecules containing at most one carbon atom are considered based on the experimental observations. Obtaining a good match between the experimental data and the simulation requires the inclusion of reactions involving the excited state \(\hbox {O}(^{1}\hbox {D})\). The key role of \(\hbox {CH}_3\) radical is also emphasized. The good match obtained between the experiment and the simulation allows to draw the main reaction pathways of the low-pressure \(\hbox {CO}_2\)-\(\hbox {CH}_4\) plasmas, in particular to identify the main back reaction mechanisms for \(\hbox {CO}_2\). The role of \(\hbox {CH}_2\)O and \(\hbox {H}_2\)O in the gas phase is also discussed in depth as they appear to play an important role on catalytic surface studied in the part II of this study.