Mapping of trace hydrocarbon concentrations in two-dimensional flames using single-photon photoionization mass spectrometry

Single-photon photoionization mass spectrometry (SPPI-MS) with a vacuum ult raviolet laser beam at 118 nm has been used to quantify trace hydrocarbons sampled with a quartz microprobe from an axisymmetric nonpremixed methane/a ir jet name. More than 20 C3-C12 hydrocarbons were detected, including line ar species, single-ring aromatics, and two- or three-ring polynuclear aroma tic hydrocarbons. For each of these species, high-resolution two-dimensiona l concentration maps were obtained that are suitable for comparison with de tailed computer models of aromatic hydrocarbon formation and growth. Prelim inary comparison with such a model indicates that the sampling process accu rately captures the spatial structure of the flame. In general, the results show that the broadband sensitivity, part-per-million detection limits, ne gligible ion fragmentation, and rapid data acquisition rate of SPPI-MS make it an ideal technique for studying the complex hydrocarbon chemistry that occurs in flames.