Laser-induced fluorescence detection of acetylene in low-pressure propane and methane flames

Abstract

Laser-induced fluorescence is used to detect and record profiles of acetylene formed as an intermediate species in 10-Torr premixed propane and methane flames. In low-temperature regions of the flames, excitation spectra confirm acetylene as the spectral carrier. The spectra of acetylene overlap those of O2 and NO in terms of both excitation and detection wavelengths, however, acetylene can be detected with relatively little interference in the vicinity of 228 nm, using a detection wavelength of 260 nm. The fluorescence lifetime of acetylene in the flame conditions studied is approximately 20 ns, much shorter than the radiative lifetime, due to a high quenching rate for all the colliders investigated. This can be exploited in low-pressure flames to avoid interference from acetylene in monitoring nitric oxide. The acetylene mole fraction in propane flames reaches its peak value at nearly the same location as that of HCO, slightly closer to the burner than the peak CH mole fraction. The acetylene fluorescence signal is easily detected in propane flames over equivalence ratios from 0.6 to 1.2, although it increases under fuel-rich conditions. In methane flames, the acetylene signal is much weaker and is undetectable for fuel-lean conditions.