Interactions of CO, NOxand H2O Under Post-Flame Conditions

Abstract

An experimental and theoretical study of the impact of NO, NO₂ and H₂O on CO oxidation has been carried out. The experiments were performed in an isothermal quartz flow reactor at atmospheric pressure in the temperature range 800-1400 K. Inlet concentrations of NO and NO₂ were 0-1 % (vol) and 0-622 ppmv, respectively, while the water vapor level was varied in the ranges 1-32% (NO absent) and 1-10% (NO present). The results show that the concentration of water vapor has a strong effect on the CO oxidation process, partly because it controls the O/OH ratio of the radical pool, and partly due to the high efficiency of H₂O in promoting H + O₂ recombination, which causes a strong inhibition of CO oxidation at high levels. Presence of NO and NO₂ has a significant impact on moist CO oxidation, In low concentrations NO enhances CO consumption in the 900-1100 K range by converting HO₂ to OH. In higher concentrations NO may catalyze recombination of radicals, thereby inhibiting the CO oxidation. The overall effect of NO depends on the radical pool composition, particularly the HO₂ level and the O/OH ratio. NO₂ is much more efficient than NO in removing radicals and presence of NO₂ has a strong inhibiting effect on CO oxidation. A chemical kinetic model has been established, which provides a good description of the effect of NO, NO₂ and H₂O on CO oxidation, based on the calculations, the rate determining steps in the system have been identified. The present results are significant for understanding the impact of NO_x, on fuel oxidation and CO burnout in practical systems. Furthermore, they indicate that presence of NO₂ impurities may affect significantly experiment on NO containing systems.