The effect of flame structure on soot particle inception is studied by
varying the mixture fraction at stoichiometry Z(st) and, consequently
, flame location. Z(st) is varied by reassigning the nitrogen from the
oxidizer to the fuel such that the flame temperature is not changed.
Strain rates in the counterflow flame and flame heights in the coflow
flame are measured in ethylene flames to identify the sooting limits b
ased on the appearance of luminous soot. Numerical experiments with a
counterflow diffusion-flame code employing C2 kinetics are also perfor
med to understand the effects of Z(st) on flame structure and to inter
pret the experimental results. The results show that as Z(st) is incre
ased and the flame shifts towards the fuel, soot inception is suppress
ed. In the counterflow flame, no luminous soot is detected at a strain
rate greater than 60 s(-1) for Z(st) greater than or equal to 0.16, a
s compared to 175 s(-1) for the ethylene/air flame, Z(st) = 0.064. The
laminar ethylene coflow flame is soot free at Z(st) greater than or e
qual to 0.72, regardless of flame height. For small Z(st), where chang
es in Z(st) are primarily due to changes in fuel concentration, the ef
fect on soot inception is primarily fuel dilution. For large Z(st), wh
ere the oxygen concentration is appreciably increased, the subsequent
shift in the OH profile towards the fuel side of the flame can have a
dramatic influence on inception. The shift in OH essentially narrows t
he soot zone suggesting that it may be possible to obtain soot-free co
nditions for many fuels if the structure of the flame can be adjusted
to the extent that significant OH exists on the fuel side of the flame
at a temperature of ca. 1300 K. The experimental and numerical result
s demonstrate that this requirement can be satisfied for ethylene flam
es.