A computational study of ethylene–air sooting flames: Effects of large polycyclic aromatic hydrocarbons

Abstract: An updated reduced gas-phase kinetic mechanism was developed and integrated with aerosol models to predict soot formation characteristics in ethylene nonpremixed and premixed flames. A primary objective is to investigate the sensitivity of the soot formation to various chemical pathways for large polycyclic aromatic hydrocarbons (PAH). The gas-phase chemical mechanism adopted the KAUST-Aramco PAH Mech 1.0, which utilized the AramcoMech 1.3 for gas-phase reactions validated for up to C2 fuels. In addition, PAH … Show more

“…The change in the chemical mechanism from NBP to KAM1.0 consistently increases soot volume fraction for all the soot models considered, consistent with previous studies in laminar flames [22] . While the qualitative volume fraction profiles are the same, there is 50-200% increase in soot volume fraction.…”

“…• The KAM1.0 mechanism produces more soot mass compared to the NBP mechanism for all statistical approaches considered, which is consistent with laminar flame results [22] . While the nucleation and condensation source terms are much higher with KAM1.0 compared to NBP, the final soot mass fraction changes by less than a factor of two.…”

“…On the other hand, recent nucleation models including higher PAHs up to coronene (A7) have shown improved soot prediction in laminar counterflow flames [21,22] . Moreover, the predictions were also found to be sensitive to the flow configuration used [2,26] .…”

“…The NBP mechanism includes PAH chemistry up to four aromatic rings (pyrene), and the KAM1.0 mechanism includes PAH chemistry up to seven aromatic rings (coronene). Both mechanisms have been validated against canonical laminar flames [22,30,38] .…”

“…While several models are available, the two main concepts are based on (a) an acetylene-based inception model [4,17] and (b) a polycyclic-aromatic hydrocarbon (PAH) based nucleation model [18][19][20][21][22] . Both models have been used extensively to simulate a variety of turbulent sooting flames [5,7,[23][24][25][26] with a range of predictive success.…”

Effect of soot model, moment method, and chemical kinetics on soot formation in a model aircraft combustor

“…The change in the chemical mechanism from NBP to KAM1.0 consistently increases soot volume fraction for all the soot models considered, consistent with previous studies in laminar flames [22] . While the qualitative volume fraction profiles are the same, there is 50-200% increase in soot volume fraction.…”

“…• The KAM1.0 mechanism produces more soot mass compared to the NBP mechanism for all statistical approaches considered, which is consistent with laminar flame results [22] . While the nucleation and condensation source terms are much higher with KAM1.0 compared to NBP, the final soot mass fraction changes by less than a factor of two.…”

“…On the other hand, recent nucleation models including higher PAHs up to coronene (A7) have shown improved soot prediction in laminar counterflow flames [21,22] . Moreover, the predictions were also found to be sensitive to the flow configuration used [2,26] .…”

“…The NBP mechanism includes PAH chemistry up to four aromatic rings (pyrene), and the KAM1.0 mechanism includes PAH chemistry up to seven aromatic rings (coronene). Both mechanisms have been validated against canonical laminar flames [22,30,38] .…”

“…While several models are available, the two main concepts are based on (a) an acetylene-based inception model [4,17] and (b) a polycyclic-aromatic hydrocarbon (PAH) based nucleation model [18][19][20][21][22] . Both models have been used extensively to simulate a variety of turbulent sooting flames [5,7,[23][24][25][26] with a range of predictive success.…”

Effect of soot model, moment method, and chemical kinetics on soot formation in a model aircraft combustor

Formation and growth mechanisms of polycyclic aromatic hydrocarbons: A mini-review

Study on sooting behavior of premixed C1–C4 n-alkanes/air flames using a micro flow reactor with a controlled temperature profile