Add to ORKGA comprehensive, semi-detailed kinetic scheme was used to simulate the chemical structures of counterflow diffusion and fuel-rich premixed 1,3-butadiene flames, to better understand the formation of polycyclic aromatic hydrocarbons (PAH). The results showed that model predictions were in good agreement with the experiments for most of the species in both the flames. In the counterflow flames higher-molecular weight products are slightly over predicted. The pathways characterizing the pollutant formation are very different in the premixed and in the counterflow flames confirming or suggesting the need to verify and refine the detailed mechanisms tuned for premixed conditions when they are extrapolated and used in diffusion flames. Reaction p...
In this work, experimental and kinetic modeling investigations were combined to study the PAH format...
In order to understand the interactions between 2-butanol and hydrocarbon fuels in combustion chemis...
A detailed kinetic model has been developed and used to simulate aromatic growth in premixed benzene...
The chemical structure of an opposed-flow, methane diffusion flame is studied using a chemical kinet...
Polycyclic aromatic hydrocarbons (PAHs) have been heralded as mutagenic and carcinogenic substances ...
The chemical structure of an opposed flow, methane diffusion flame is studied using a chemical kinet...
In order to understand the interactions between butanol and hydrocarbon fuels in the PAH formation, ...
A kinetic mechanism, previously developed and successfully applied to predict the formation of benze...
The reduction of soot emissions from technical combustion devices requires the development of chemic...
A sooting, ethylene coflow diffusion flame has been numerically studied. A detailed kinetic mechanis...
Methane is probably the most frequently studied hydrocarbon fuel. Both its oxidation mechanism and i...
In this work, experimental and kinetic modeling investigations were combined to study the PAH format...
In order to understand the interactions between 2-butanol and hydrocarbon fuels in combustion chemis...
A detailed kinetic model has been developed and used to simulate aromatic growth in premixed benzene...
The chemical structure of an opposed-flow, methane diffusion flame is studied using a chemical kinet...
Polycyclic aromatic hydrocarbons (PAHs) have been heralded as mutagenic and carcinogenic substances ...
The chemical structure of an opposed flow, methane diffusion flame is studied using a chemical kinet...
In order to understand the interactions between butanol and hydrocarbon fuels in the PAH formation, ...
A kinetic mechanism, previously developed and successfully applied to predict the formation of benze...
The reduction of soot emissions from technical combustion devices requires the development of chemic...
A sooting, ethylene coflow diffusion flame has been numerically studied. A detailed kinetic mechanis...
Methane is probably the most frequently studied hydrocarbon fuel. Both its oxidation mechanism and i...
In this work, experimental and kinetic modeling investigations were combined to study the PAH format...
In order to understand the interactions between 2-butanol and hydrocarbon fuels in combustion chemis...
A detailed kinetic model has been developed and used to simulate aromatic growth in premixed benzene...