The reaction of active nitrogen with acetylene. I

Abstract

The reaction between active nitrogen and acetylene was studied in a low-pressure flow reactor using a leak to a mass spectrometer as the analytical device and varying reaction time from a few to 45 ms. In mixtures in which the initial ratio of acetylene to atomic nitrogen is larger than unity a comparatively slow reaction takes place whose main products are cyanogen, hydrogen and cyanoacetylene. The reaction is accelerated by rising pressure and temperature. The proposed rate determining steps are C ₂ H ₂ + N ^K1 ⇆ _K-1 C ₂ H ² N*, C ₂ H ₂ N*+ N ₂ → ^K2 C ₂ H ₂ N+ N ₂ with K ₁ = 1·1X 10 ^-12(+-0·12) exp (-2000(±400)/ RT ) cm ³ molecule ^-1 s ^-1 and k _-1 = 4x10 ^-s T ^e s ^-1 , if k ₂ is taken to be the collisional frequency. The radical C ₂ H ₂ N is found to react competitively with nitrogen atoms and with acetylene to form the end products. At low (≤ 0·5) initial acetylene to atomio nitrogen ratios a much faster reaction occurs which is accompanied by chemiluminescence of CH and CN radicals and whose main products are hydrogen cyanide, cyanogen and hydrogen. Simultaneously, a rapid recombination of nitrogen atoms takes place, as many as 20 atoms reacting per molecule of acetylene consumed. This rapid reaction has a negative temperature coefficient. It is suggested that this is a chain reaction started by metastable nitrogen molecules ( A ³ Σ ⁺ _u ) nitrogen atoms which react with acetylene to form hydrogen cyanide and cyanide radicals. The latter cause the recombination of nitrogen atoms by the chain reactions CN + N + N ₂ → NCN + N ₂ NCN+N → N* ₂ + CN, with 3 x 10-30 6 < 2 x 10 ^-29 cm ₆ molecule ^-2 s ^-1 . These chains are broken by recombination of cyanide radicals and by the reactions of CN and NCN radicals with acetylene. Cyanogen also causes a catalytic recombination of nitrogen atoms. Ammonia added to acetylene-active nitrogen mixtures suppresses the rapid reaction but has no effect on the slow reaction in richer mixtures.