The inhibiting effect of NO addition on dimethyl ether high-pressure oxidation

The high-pressure dimethyl ether (DME, CH₃OCH₃) oxidation has been investigated in a plug flow reactor in the 450–1050 K temperature range. Different pressures (20, 40 and 60 bar), air excess ratios (λ = 0.7, 1 and 35), and the absence/presence of NO have been tested, for the first time under these conditions. An early reactivity of DME and a negative temperature coefficient (NTC) zone have been observed under the studied conditions, although under very oxidizing conditions (λ = 35), NTC zone is almost imperceptible because DME is completely consumed at lower temperatures. A chemical kinetic mechanism has been used to describe the DME high-pressure oxidation, with a good agreement with the experimental trends observed. In general, modeling calculations with the present mechanism have been successfully compared with experimental data from literature. The presence of NO has an inhibiting effect on DME high-pressure consumption at low-temperatures because of: (i) the competition between CH₃OCH₂+O₂⇌CH₃OCH₂O₂ and CH₃OCH₂+NO₂⇌CH₃OCH₂O+NO reactions, and (ii) the participation of NO in CH₃OCH₂O₂+NO⇌CH₃OCH₂O+NO₂ reaction, preventing CH₃OCH₂O₂ radicals continue reacting through a complex mechanism, which includes a second O₂ addition and several isomerizations and decompositions, during which highly reactive OH radicals are generated. Consequently, NO and NO₂ are interchanged in a cycle but never consumed.