Towards a kinetic understanding of the NO_x promoting-effect on ignition of coalbed methane: A case study of methane/nitrogen dioxide mixtures

Nitrogen dioxide (NO₂) is an important impurity in coal-bed methane (CBM) and a dominant component of NO_x pollution in practical engines. Its promoting effect on methane ignition has been studied in the current experimental and kinetic study. Ignition delay times of NO₂/CH₄/O₂/Ar mixtures, with blending ratios of NO₂:CH₄ of 30:70, 50:50 and 70:30 for stoichiometric methane mixtures were measured in a shock tube. Experiments cover a range of pressures (1.2-10.0 atm) and temperatures (933-1961 K). Under all tested pressures, NO₂ addition promotes the reactivity of methane and reduces the global activation energy at all pressures, and these effects are most significant for the mixtures with highest NO₂ concentrations, at the highest pressures and at the lowest temperatures. To simulate the experimental measurements, five literature NO_x sub-mechanisms were integrated with AramcoMech 1.3. The simulations demonstrate that, for the mixtures with low levels of NO_x concentrations, the five models agree well with the experimental ignition delay times. For the mixtures with high NO_x content, however, all five models are unable to reproduce the measured data, and the level of disagreement increases with increasing NO₂ concentration. An updated mechanism is proposed, based on modifications made as a result of sensitivity and reaction flux analyses performed to quantitatively determine the chemical reasons for NO₂ promoting methane ignition. The results indicate that, NO₂ addition perturbs the branching ratio of key reaction pathways by affecting the structure of the free radical pool at the initial ignition stage of methane oxidation. A new reaction cycle via the following sequence of reactions ĊH₃ + NO₂ ⇔ CH₃Ȯ + NO, CH₃Ȯ + M ⇔ CH₂O + H + M, NO₂ + ⇔ NO + ȮH, and CH₄ + ȮH ⇔ ĊH₃ + H₂O is proposed to explain the observed effect of NO₂ addition on the promotion of methane ignition.