Aspects of soot dynamics as revealed by measurements of broadband fluorescence and flame luminosity in flickering diffusion flames

Abstract Numerous investigators have attributed laser-induced broadband fluorescence observed in both rich, premixed flames and in diffusion flames to small polycyclic aromatic hydrocarbons (PAH). However, the wide variety of experimental flame conditions and excitation/detection wavelengths have clouded the interpretation of such measurements, for example, in terms of indicating either the presence of soot precursors or unreactive by-products (or both). This paper presents PAH fluorescence measurements excited at 283.5 nm and detected at 400–447 nm in a series of steady and flickering methane, propane, and ethylene diffusion flames burning at atmospheric pressure in an axisymmetric, coflow configuration. In the flickering flame experiments, acoustic forcing of the fuel rate is used to phase lock the periodic flame flicker close to the natural flame flicker frequency caused by buoyancy-induced instabilities. When compared to our earlier measurements of soot concentrations in the same flames, soot inception in the annular region is found to occur at the interface between the fluorescing PAH and the region of high radical concentrations. Although the peak PAH fluorescence signals and maximum soot concentrations do not occur at the same spatial locations, indirect evidence is presented that the species responsible for PAH fluorescence participate in either soot inception or growth. In contrast to prior suggestions that PAH fluorescence intensities scale with soot concentrations, the relative peak PAH fluorescence signals are observed to be 1.0:9.8:5.4 for the steady methane, propane, and ethylene flames, respectively, whereas the maximum soot levels follow a different trend of 1.0:19:39. Similar results are observed in the flickering flames, all of which exhibit enhanced PAH fluorescence signals compared to the steady flames. PAH fluorescence excited at 560.3 nm in the steady flames is also strongest for propane. Measurements of flame radiation arising from soot particles have also been made, with detection at 395–547 nm and to a limited degree at 833–900 nm. Visible flame emission is particularly sensitive to the local soot temperature. Comparison of the luminosity images with those of OH· fluorescence and soot scattering shows that the luminosity is strongest where the hydroxyl radicals and soot layers overlap, i.e., in regions of active soot oxidation.

[1]  F. Beretta,et al.  Ultraviolet and visible fluorescence in the fuel pyrolysis regions of gaseous diffusion flames , 1985 .

[2]  P. Andreussi,et al.  BOUNDARY-LAYER BURNING OF FUEL SURFACES - THE SOOT FIELD , 1986 .

[3]  F. Beretta,et al.  U.V. and Visible Laser Excited Fluorescence from Rich Premixed and Diffusion Flames , 1992 .

[4]  F. Cignoli,et al.  Time-delayed detection of laser-induced incandescence for the two-dimensional visualization of soot in flames. , 1994, Applied optics.

[5]  L. Petarca,et al.  Fluorescence spectra and polycyclic aromatic species in a N-heptane diffusion flame , 1989 .

[6]  R. L. Wal Onset of Carbonization: Spatial Location Via Simultaneous LIF-LII and Characterization Via TEM , 1996 .

[7]  Christopher R. Shaddix,et al.  Computations of enhanced soot production in time-varying CH4/air diffusion flames , 1996 .

[8]  M. Castaldi,et al.  Formation of polycyclic aromatic hydrocarbons (PAH) in methane combustion: Comparative new results from premixed flames , 1996 .

[9]  Damon Honnery,et al.  A soot formation rate map for a laminar ethylene diffusion flame , 1990 .

[10]  I. Kennedy The Suppression of Soot Particle Formation in Laminar and Turbulent Diffusion Flames , 1988 .

[11]  J. Lahaye,et al.  An experimental investigation into soot formation and distribution in polymer diffusion flames , 1980 .

[12]  K. Sattler,et al.  New aspects of growth mechanisms for polycyclic aromatic hydrocarbons in diffusion flames , 1995 .

[13]  Robert J. Santoro,et al.  The oxidation of soot and carbon monoxide in hydrocarbon diffusion flames , 1994 .

[14]  N. Laurendeau,et al.  Flame temperature measurements using the anomalous fluorescence of pyrene. , 1988, Applied optics.

[15]  Robert J. Santoro,et al.  Soot inception in a methane/air diffusion flame as characterized by detailed species profiles , 1985 .

[16]  Christopher R. Shaddix,et al.  Quantitative Measurements of Enhanced Soot Production in a Flickering Methane/Air Diffusion Flame , 1994 .

[17]  Michael G. Littman,et al.  Comparative study of soot formation on the centerline of axisymmetric laminar diffusion flames: Fuel and temperature effects , 1987 .

[18]  N. Laurendeau,et al.  Determination of flame temperature using the anomalous fluorescence of pyrene. , 1986, Optics letters.

[19]  S. Harris,et al.  Optical detection of large soot precursors , 1989 .

[20]  Forman A. Williams,et al.  Structure of Laminar Coflow Methane–Air Diffusion Flames , 1986 .

[21]  J. Steinfeld,et al.  Fluorescence excitation and emission spectra of polycyclic aromatic hydrocarbons at flame temperatures , 1980 .

[22]  D. Honnery,et al.  Soot and Mixture Fraction in Turbulent Diffusion Flames , 1987 .

[23]  Robert J. Santoro,et al.  The Transport and Growth of Soot Particles in Laminar Diffusion Flames , 1987 .

[24]  J. Winefordner,et al.  Laser-Induced Fluorescence in Kerosene/Air and Gasoline/Air Flames , 1980 .

[25]  A. G. Gaydon,et al.  Absorption spectra of ethylene diffusion flames , 1971 .

[26]  Baki M. Cetegen,et al.  Experiments on the periodic instability of buoyant plumes and pool fires , 1993 .

[27]  J. Longwell,et al.  Soot and Tar Production in a Jet-Stirred/Plug-Flow Reactor System: High and Low C2H2 Concentration Environments , 1994 .

[28]  B. Haynes,et al.  Identification of a source of argon-ion-laser excited fluorescence in sooting flames , 1981 .

[29]  David T. Anderson,et al.  Mechanistic studies of toluene destruction in diffusion flames , 1990 .

[30]  K. Sattler,et al.  Reactive Dimerization: A New PAH Growth Mechanism in Flames , 1995 .

[31]  C. Shaddix,et al.  Laser-induced incandescence measurements of soot production in steady and flickering methane, propane, and ethylene diffusion flames , 1996 .

[32]  A. A. Westenberg Eleventh symposium (International) on combustion , 1967 .

[33]  J. E. Harrington,et al.  Laser-induced fluorescence measurements of formaldehyde in a methane/air diffusion flame , 1993 .

[34]  Anthony P. Hamins,et al.  Concentration measurements of OH· and equilibrium analysis in a laminar methane-air diffusion flame , 1990 .

[35]  Reginald E. Mitchell,et al.  Experimental and numerical investigation of confined laminar diffusion flames , 1980 .

[36]  Robert J. Santoro,et al.  Soot particle measurements in diffusion flames , 1983 .

[37]  W. Mallard,et al.  The observation of laser-induced visible fluorescence in sooting diffusion flames , 1982 .

[38]  R. Harvey,et al.  Absorption Spectroscopy Measurement of Methyl Radical Concentrations in Low Pressure Flames , 1973 .

[39]  A. G. Gaydon,et al.  The identification of molecular spectra , 1950 .

[40]  J. T. Mckinnon,et al.  Infrared analysis of flame-generated PAH samples , 1996 .

[41]  J. Longwell,et al.  Polycyclic aromatic hydrocarbons from the high-temperature pyrolysis of pyrene , 1994 .

[42]  Alan Williams,et al.  A mechanism for the formation of soot particles and soot deposits , 1992 .

[43]  S. Ray,et al.  Polycyclic aromatic hydrocarbons from diffusion flames and diesel engine combustion , 1964 .

[44]  R. Long,et al.  Formation of polycyclic aromatics in rich premixed acetylene and ethylene flames , 1973 .

[45]  William M. Pitts,et al.  Greatly enhanced soot scattering in flickering CH4/Air diffusion flames , 1993 .

[46]  T. S. Norton,et al.  Comparison of Experimental and Computed Species Concentration and Temperature Profiles in Laminar, Two-Dimensional Methane/Air Diffusion Flames , 1993 .

[47]  Phillip H. Paul,et al.  Planar laser-induced-fluorescence imaging measurements of OH and hydrocarbon fuel fragments in high-pressure spray-flame combustion. , 1995, Applied optics.