Effect of simultaneous H₂ and NH₃ addition on soot formation in co-flow diffusion CH₄ flame

Simultaneous blending of hydrogen (H₂) and ammonia (NH₃) to hydrocarbon fuels can tackle the safety issues of H₂ and improve burning efficiency of NH₃. While this strategy brings challenges for soot prediction due to the promotion effect of H₂ and the suppression effect of NH₃, and the interactions between H₂ and NH₃. In this study, the simultaneous addition of NH₃ and H₂ on soot formation was experimentally and numerically investigated in a co-flow diffusion CH₄ flame. The interactions between NH₃ and H₂, and how they impacted different soot formation processes were comprehensively revealed using a detailed soot sectional model. The decrease of peak SVF in CH₄ flame caused by NH₃ was 0.013 ppm, about 31.6 % smaller than that in CH₄/H₂ flame (0.019 ppm), indicating that the inhibitive effect of NH₃ on soot formation was promoted by H₂. The existence of H₂ promoted the suppression effect of NH₃ on soot nucleation, condensation and HACA processes in the CH₄ flame. Compared with CH₄/NH₃ flame, the pyrolysis rates of NH₃, NH₂ and NH in the CH₄/NH₃/H₂ flame were higher since more H and OH radicals were generated via H₂ decomposition. This led to a larger consumption rate of H and OH radicals, which decreased the reaction rates of CH₄+OH=CH₃+H₂O and C₂H₄+OH=C₂H₃+H₂O, and promoted the combination of NO and C₂H. Both factors accounted for a stronger suppression effect of NH₃ on the formation of A1 in CH₄/H₂ flame than that in CH₄ flame, and thus a stronger inhibitive effect on soot inception and condensation. Compared with the CH₄ flame, NH₃ resulted in a larger decline of H and OH radicals mole fractions in the CH₄/H₂ flame, which explained the stronger suppression effect of NH₃ on the HACA surface growth process in the CH₄/H₂ flame.