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Michelsen HA. Derivation of a temperature-dependent accommodation coefficient for use in modeling laser-induced incandescence of soot. Applied Physics B [Internet]. 2009;94:103-117.\par \par Goulay F, Schrader PE, Nemes L, Dansson MA, Michelsen HA. Photochemical interferences for laser-induced incandescence of flame-generated soot. Proceeding of the Combustion Institute [Internet]. 2009;32:963-970.\par \par Bladh H, Johnsson J, Bengtsson P-E. On the dependence of the laser-induced incandescence (LII) signal on soot volume fraction for variations in particle size. Applied Physics B: Lasers and Optics [Internet]. 2008;90:109-125.\par \par Michelsen HA, Linne MA, Kock BF, Hofmann M, Tribalet B, Schulz C. Modeling laser-induced incandescence of soot: Enthalpy changes during sublimation, conduction, and oxidation. Applied Physics B [Internet]. 2008;93:645-656.\par \par Maffi S, Cignoli F, Bellomunno C, De Iuliis S, Zizak G. Spectral effects in laser induced incandescence application to flame-made titania nanoparticles. Spectrochimica Acta Part B. 2008;63:202-209.\par \par De Iuliis S, Migliorini F, Cignoli F, Zizak G. 2D soot volume fraction imaging in an ethylene diffusion flame by two-color laser-induced incandescence (2C-LII) technique and comparison with results from other optical diagnostics. Proceedings of The Combustion Institute. 2007;31:869-976.\par \par Dansson MA, Boisselle M, Linne MA, Michelsen HA. Complications to optical measurements using a laser with an unstable resonator: A case study on laser-induced incandescence of soot. Applied Optics. 2007;46:8095-8103.\par \par Michelsen HA, Liu F, Kock BF, Bladh H, Boiarciuc A, Charwath M, Dreier T, Hadef R, Hofmann M, Reimann J. Modeling laser-induced incandescence of soot: A summary and comparison of LII models. Applied Physics B. 2007;87:503-521.\par \par Michelsen HA, Tivanski AV, Gilles MK, van Poppel LH, Dansson MA, Buseck PR. Particle formation from pulsed laser irradiation of soot aggregates studied with a scanning mobility particle sizer, a transmission electron microscope, and a scanning transmission x-ray microscope. Applied Optics. 2007;46:959-977.\par \par Bougie B, Ganippa LC, Van Vliet AP, Meerts WL, Dam NJ, ter Meulen JJ. Soot particulate size characterisation in a heavy-duty Diesel engine for different engine loads by laser-induced incandescence. In: Proceedings of the Combustion Institute. Vol. 31. Heidelberg; 2007. p. 685-691.\par \par Liu F, Stagg BJ, Snelling DR, Smallwood GJ. Effects of primary soot particle size distribution on the temperature of soot particles heated by a nanosecond pulsed laser in an atmospheric laminar diffusion flame. International Journal of Heat and Mass Transfer [Internet]. 2006;49:777-788.\par \par Bladh H, Bengtsson P-E, Delhay J, Bouvier Y, Therssen E, Desgroux P. Experimental and theoretical comparison of spatially resolved laser-induced incandescence (LII) signals of soot in backward and right-angle configuration. Applied Physics B: Lasers and Optics [Internet]. 2006;83:423 - 433.\par \par Liu F, Daun KJ, Snelling DR, Smallwood GJ. Heat conduction from a spherical nano-particle: status of modeling heat conduction in laser-induced incandescence. Applied Physics B. 2006;83:355 - 382.\par \par Liu F, Daun KJ, Snelling DR, Smallwood GJ. Heat conduction from a spherical nano-particle: status of modeling heat conduction in laser-induced incandescence. Applied Physics B: Lasers and Optics [Internet]. 2006;83:355 - 382.\par \par Liu F, Yang M, Hill FA, Snelling DR, Smallwood GJ. Influence of polydisperse distributions of both primary particle and aggregate size on soot temperature in low-fluence LII. Applied Physics B: Lasers and Optics [Internet]. 2006;83:383 - 395.\par \par Charwath M, Suntz R, Bockhorn H. Influence of Temporal Resolution on Time-Resolved Laser-Induced Incandescence Signal Evolutions. Applied Physics B: Lasers and Optics [Internet]. 2006;83:435 - 442.\par \par Thomson KA, Snelling DR, Smallwood GJ, Liu F. Laser induced incandescence measurements of soot volume fraction and effective particle size in a laminar co-annular non-premixed methane/air flame at pressures between 0.5\'e2??4.0 MPa. Applied Physics B: Lasers and Optics [Internet]. 2006;83:469 - 475.\par \par Beyer V, Greenhalgh DA. Laser Induced Incandescence under High Vacuum Conditions. Applied Physics B: Lasers and Optics [Internet]. 2006;83:455 - 467.\par \par Schulz C. Laser-Induced Incandescence. Applied Physics B: Lasers and Optics [Internet]. 2006;83:331.\par \par Michelsen HA. Laser-induced incandescence of flame-generated soot on a picosecond timescale. Applied Physics B: Lasers and Optics [Internet]. 2006;83:443 - 448.\par \par Bougie B, Ganippa LC, Van Vliet AP, Meerts WL, Dam NJ, ter Meulen JJ. Laser-induced incandescence particle size measurements in a heavy-duty diesel engine. Combustion and Flame [Internet]. 2006;145:635-637.\par \par Suntz R, Bockhorn H. Laser-induced incandescence: Quantitative Interpretation, Modelling, Applications Suntz R, Bockhorn H. Proc. 2nd Intl. Discussion Meeting and Workshop [Internet]. 2006;211.\par \par Schulz C, Kock BF, Hofmann M, Michelsen H, Will S, Bougie B, Suntz R, Smallwood GJ. Laser-induced incandescence: recent trends and current questions. Applied Physics B: Lasers and Optics [Internet]. 2006;83:333 - 354.\par \par Dreier T, Bougie B, Dam N, Gerber T. Modeling of time-resolved laser-induced incandescence transients for particle sizing in high-pressure spray combustion environments: a comparative study. Applied Physics B: Lasers and Optics [Internet]. 2006;83:403-411.\par \par Bougie B, Ganippa LC, Dam NJ, ter Meulen JJ. On particulate characterisation in a heavy-duty Diesel engine by time-resolved laser-induced incandescence. Appl. Phys B, Lasers and Optics [Internet]. 2006;83:477-485.\par \par De Iuliis S, Migliorini F, Cignoli F, Zizak G. Peak soot temperature in laser-induced incandescence measurements. Appl.Phys. B. 2006;83:397-402.\par \par Boiarciuc A, Foucher F, Mouna\{\\"?m-Rousselle C. Soot volume fractions and primary particle size estimate by means of the simultaneous two-color-time-resolved and 2D laser-induced incandescence. Applied Physics B: Lasers and Optics [Internet]. 2006;83:413 - 421.\par \par Eremin A, Gurentsov E, Hofmann M, Kock BF, Schulz C. TR-LII for sizing of carbon particles at room temperature. Applied Physics B: Lasers and Optics [Internet]. 2006;83:449 - 454.\par \par De Iuliis S, Cignoli F, Zizak G. Two-color laser-induced incandescence (2C-LII) technique for absolute soot volume fraction measurements in flames: erratum. Applied Optics. 2006;45:3805.\par \par Kock BF, Schulz C, Roth P. Two-color time-resolved LII applied to soot particle sizing in the cylinder of a diesel engine. Combustion and Flame. 2006:submitted.\par \par Delhay J, Bouvier Y, Therssen E, Black JD, Desgroux P. 2D imaging of laser wing effects and of soot sublimation in laser-induced incandescence measurements. Appl. Phys. B. 2005;81:181-186.\par \par Yoder GD, Diwakar PK, Hahn DW. Assessment of soot particle vaporization effects during laser-induced incandescence with time-resolved light scattering. Appl. Opt. 2005;20:4211-4219.\par \par Snelling DR, Smallwood GJ, Liu F, G\'fclder \'d6L, Bachalo WD. A calibration-independent laser-induced incandescence technique for soot measurement by detecting absolute light intensity. Applied Optics [Internet]. 2005;44:6773-6785.\par \par Kr\'fcger V, Wahl C, Hadef R, Geigle KP, Stricker W, Aigner M. Comparison of laser-induced incandescence method with scanning mobility particle sizer technique: The influence of probe sampling and laser heating on soot particle size distribution. Measurement Science & Technology. 2005;16:1477-1486.\par \par Kock BF, Kayan C, Knipping J, Orthner HR, Roth P. Comparison of LII and TEM sizing during synthesis of iron particle chains. Proceedings of the Combustion Institute [Internet]. 2005;30:1689-1697.\par \par Witze PO, Gershenzon M, Michelsen HA. Dual-Laser LIDELS: An Optical Diagnostic for Time-Resolved Volatile Fraction Measurements of Diesel Particulate Emissions.  [Internet]. 2005.\par \par Liu F, Smallwood GJ, Snelling DR. Effects of primary particle diameter and aggregate size distribution on the temperature of soot particles heated by pulsed lasers. Journal of Quantitative Spectroscopy and Radiative Transfer [Internet]. 2005;93:301-312.\par \par Geigle KP, Schneider-K\'fchnle Y, Tsurikov MS, Hadef R, L\'fcckerath R, Kr\'fcger V, Stricker W, Aigner M. Investigation of laminar pressurized flames for soot model validation using SV-CARS and LII. Proceedings of the Combustion Institute. 2005;30:1645-1653.\par \par Tsurikov MS, Geigle KP, Kr\'fcger V, Schneider-K\'fchnle Y, Stricker W, L\'fcckerath R, Hadef R, Aigner M. Laser-based investigation of soot formation in laminar premixed flames at atmospheric and elevated pressures. Combustion Science and Technology [Internet]. 2005;177:1835-1862.\par \par Schulz C. Laser-induced incandescence: Quantitative Interpretation, Modelling, Application Schulz C. Proc. Intl. Bunsen Discussion Meeting and Workshop [Internet]. 2005;195.\par \par Hadef R, Kr\'fcger V, Geigle KP, Tsurikov MS, Schneider-K\'fchnle Y, Aigner M. Mesures de la taille et de la concentration de la suie dans une flamme laminaire premelangee. International Review of the Institut Fran\'c3\'a7ais du Petrole. 2005:in press.\par \par Bougie B, Tulej M, Dreier T, Dam NJ, ter Meulen JJ, Gerber T. Optical diagnostics of diesel spray injections and combustion in a high-pressure high-temperature cell. Applied Physics B: Lasers and Optics [Internet]. 2005;80:1039-1045.\par \par Meyer TR, Roy S, Belovich VM, Corporan E, Gord JAR. Simultaneous planar laser-induced incandescence, OH planar laser-induced fluorescence, and droplet Mie scattering in swirl-stabilized spray flames. Appl. Opt. 2005;44:445-454.\par \par Bougie B, Ganippa LC, Van Vliet AP, Dam N, Meerts WL, ter Meulen JJ. Soot characterization with laser induced incandescence in a heavy duty diesel engine. In: European Combustion Meeting 2005. Louvain la Neuve, Belgium; 2005.\par \par Thomson KA, G\'fclder \'d6L, Weckman EJ, Fraser RA, Smallwood GJ, Snelling DR. Soot concentration and temperature measurements in co-annular, nonpremixed CH4/air laminar flames at pressures up to 4 MPa. Combustion and Flame [Internet]. 2005;140:222-232.\par \par De Iuliis S, Cignoli F, Zizak G. Two-color laser-induced incandescence (2C-LII) technique for absolute soot volume fraction measurements in flames. Applied Optics. 2005;44:7414-7423.\par \par Bladh H, Bengtsson P-E. Characteristics of laser-induced incandescence from soot in studies of a time-dependent heat- and mass-transfer model. Applied Physics B: Lasers and Optics. 2004;78:241-248.\par \par Snelling DR, Liu F, Smallwood GJ, G\'fclder \'d6L. Determination of the soot absorption function and thermal accommodation coefficient using low-fluence LII in a laminar coflow ethylene diffusion flame. Combustion and Flame [Internet]. 2004;136:180-190.\par \par Tian K, Liu F, Thomson KA, Snelling DR, Smallwood GJ, Wang D. Distribution of the number of primary particles of soot aggregates in a nonpremixed laminar flame. Combustion and Flame [Internet]. 2004;138:195-198.\par \par Stipe CB, Choi JH, Lucas D, Koshland CP, Sawyer RF. Nanoparticle production by UV irradiation of combustion generated soot particles. J. Nanoparticle Res. 2004;6:467-477.\par \par Snelling DR, Smallwood GJ, G\'fclder \'d6L, Liu F. Small particle analysis by laser induced incandescence.  [Internet]. 2004.\par \par Moreau SC, Therssen E, Mercier X, Pauwels JF, Desgroux P. Two-color laser-induced incandescence and cavity ring-down spectroscopy for sensitive and quantitative imaging of soot and PAHs in flames. Applied Physics B: Lasers and Optics. 2004;78:485-492.\par \par Schoemaecker Moreau C, Therssen E, Mercier X, Pauwels JF, Desgroux P. Two-color laser-induced incandescence and cavity ring-down spectroscopy for sensitive and quantitative imaging of soot and PAHs in flames. Appl. Phys. B. 2004;78:485-492.\par \par Hofmann M, Bessler WG, Schulz C, Jander H. Laser-Induced Incandescence for Soot Diagnostics at High Pressures. Applied Optics [Internet]. 2003;42:2052-2062.\par \par Hofmann M, Bessler WG, Schulz C, Jander H. Laser-induced incandescence (LII) for soot diagnostics at high pressure. Appl. Opt. 2003;42:2052-2062.\par \par Starke R, Kock BF, Roth P. Nano-particle sizing by laser-induced incandescence (LII) in a shock wave reactor. Shock Waves. 2003;12:351-360.\par \par Lehre T, Jungfleisch B, Suntz R, Bockhorn H. Size distributions of nanoscaled particles and gas temperatures from time-resolved laser-induced incandescence measurements. Applied Optics. 2003;42:2021-2030.\par \par Allouis C, Beretta F, D?Alessio A. Sizing soot and micronic carbonaceous particle in spray flames base on time resolved LII. Experimental Thermal and Fluid Science. 2003;27:455-463.\par \par Michelsen HA, Witze PO, Kayes D, Hochgreb S. Time-Resolved Laser-Induced Incandescence of Soot: The Influence of Experimental Factors and Microphysical Mechanisms. Applied Optics [Internet]. 2003;42:5577-5590.\par \par Kock BF, Roth P. Two-color TR-LII applied to in-cylinder Diesel particle sizing. In: Proc. of the European Combustion Meeting. Orl\'c3\'a9ans; 2003.\par \par Michelsen HA. Understanding and predicting the temporal response of laser-induced incandescence from carbonaceous particles. Journal of Chemical Physics [Internet]. 2003;118:7012-7045.\par \par Schnaiter M, Horvath H, Mohler O, Naumann K-H, Saathoff H, Schock OW. UV-VIS-NIR spectral optical properties of soot and soot-containing aerosols. Journal of Aerosol Science [Internet]. 2003;34:1421-1444.\par \par Kohse-H\'f6inghaus K, Jeffries JB. Applied Combustion Diagnostics.  2002.\par \par Smallwood GJ, Clavel DJ, Gareau D, Sawchuk RA, Snelling DR, Witze PO, Axelsson B, Bachalo WD, G\'fclder \'d6L. Concurrent Quantitative Laser-Induced Incandescence and SMPS Measurements of EGR Effects on Particulate Emissions from a TDI Diesel Engine.  [Internet]. 2002.\par \par Smallwood GJ, Clavel DJ, Gareau D, Sawchuk RA, Snelling DR, Witze PO, Axelsson B, Bachalo WD, G\'fclder \'d6L. Concurrent quantitative laser-induced incandescence and SMPS measurements of EGR effects on particulate emissions form a TDI diesel engine. SAE Technical Paper Series 2002-01-2715. 2002.\par \par Snelling DR, Liu F, Smallwood GJ, G\'fclder \'d6L. Determination of the Soot Absorption Function and Accommodation Coefficient Using Low-Fluence LII. In: Twenty-Ninth Symposium (International) on Combustion. Sapporo, Japan; 2002. p. WIP 3-1354.\par \par Neill SW, Smallwood GJ, Snelling DR, Sawchuk RA, Clavel DJ, Gareau D, Chippior WL. Effect of EGR on Heavy-Duty Diesel Engine Emissions Characterized with Laser-Induced Incandescence. In: ASME-ICED 2002 Fall Technical Conference. New Orleans; 2002.\par \par Liu F, Guo H, Smallwood GJ, G\'fclder \'d6L. Effects of gas and soot radiation on soot formation in a coflow laminar ethylene diffusion flame. Journal of Quantitative Spectroscopy and Radiative Transfer [Internet]. 2002;73:409-421.\par \par Witze PO. High-Energy, Pulsed Laser Diagnostics for Real-Time Measurements of Reciprocating Engine PM Emissions. In: 8th Diesel Engine Emissions Reduction Conference. San Diego; 2002.\par \par Kock BF, Eckhardt T, Roth P. In-cylinder sizing of diesel particles by time-resolved laser-induced incandescence (TR-LII). Proceedings of the Combustion Institute. 2002;29:2775-2782.\par \par Smallwood GJ, Stagg BJ, Bachalo WD. Investigation of LII for Online Measurement of Nanoparticle Surface Area in a Carbon Black Reactor. In: Twenty-Ninth Symposium (International) on Combustion. Sapporo, Japan; 2002. p. WIP 3-1411.\par \par Jenkins TP, Bartholomew JL, DeBarber PA, Yang P, Seitzman JM, Howard RP. Laser Induced Incandescence for Soot Concentration Measurements in Turbine Engine Exhausts.  2002.\par \par Schittkowski T, Mewes B, Br\'fcggemann D. Laser-induced incandescence and Raman measurements in sooting methane and ethylene flames. Physical Chemistry Chemical Physics. 2002;4:2063-2071.\par \par Arden C, Burnett RT, Thun MJ, Calle EE, Krewski D, Ito K, Thurston GD. Lung Cancer, Cardiopulmonary Mortality, and Long-term Exposure to Fine Particulate Air Pollution. Journal of the American Medical Association [Internet]. 2002;287:1132-1141.\par \par Leipertz A, Ossler F, Ald\'e9n M. Polycyclic Aromatic Hydrocarbons and Soot Diagnostics by Optical Techniques. New York: Taylor and Francis; 2002.\par \par Bockhorn H, Geitlinger H, Jungfleisch B, Lehre T, Sch\'c3\'b6n A, Streibel T, Suntz R. Progress in characterization of soot formation by optical techniques. Physical Chemistry Chemical Physics. 2002;4:3780-3793.\par \par Greis AE, Gr\'fcnefeld G, Becker M, Pischinger S. Quantitative measurements of the soot distribution in a realistic common rail D.I. Diesel engine. In: 11th International Symposium on Application of Laser Techniques to Fluid Mechanics. Lissabon; 2002.\par \par Hult J, Omrane A, Nygren J, Kaminski CF, Axelsson B, Collin R, Bengtsson P-E, Ald\'e9n M. Quantitative three-dimensional imaging of soot volume fraction in turbulent non-premixed flames. Experiments in Fluids. 2002;33:265-269.\par \par Witze PO. Real-Time Measurement of the Volatile Fraction of Diesel Particulate Matter Using Laser-Induced Desorption with Elastic Light Scattering (LIDELS).  [Internet]. 2002.\par \par Wang H, Zhao B, Wyslouzil B, Streletzky K. Small-Angle Neutron Scattering of Soot Formed in Laminar Premixed Ethylene Flames. In: Twenty-Ninth Symposium (International) on Combustion. Sapporo, Japan; 2002.\par \par Stipe CB, Higgins BS, Lucas D, Koshland CP, Sawyer RF. Soot Detection Using Excimer Laser Fragmentation Fluorescence Spectroscopy. In: Twenty-Ninth Symposium (International) on Combustion. Sapporo, Japan; 2002.\par \par Hessler JP, Seifert S, Winans RE. Spatially-Resolved Small-Angle X-Ray Scattering Studies of Soot Inception and Growth. In: Twenty-Ninth Symposium (International) on Combustion. Sapporo, Japan; 2002.\par \par Snelling DR, Thomson KA, Smallwood GJ, G\'fclder \'d6L, Weckman EJ, Fraser RA. Spectrally Resolved Measurement of Flame Radiation to Determine Soot Temperature and Concentration. AIAA Journal [Internet]. 2002;40:1789-1795.\par \par Snelling DR, Smallwood GJ, G\'fclder \'d6L, Liu F, Bachalo WD. A Calibration-Independent Technique of Measuring Soot by Laser-Induced Incandescence Using Absolute Light Intensity. In: The Second Joint Meeting of the US Sections of the Combustion Institute. Oakland, California; 2001.\par \par Smallwood GJ, Snelling DR, Liu F, G\'fclder \'d6L. Clouds over Soot Evaporation: Errors in Modeling Laser-Induced Incandescence of Soot. Journal of Heat Transfer [Internet]. 2001;123:814-818.\par \par Smallwood GJ, Snelling DR, Liu F, G\'fclder \'d6L. Clouds over soot evaporation: Errors in modeling laser-induced incandescence of soot. Journal of Heat Transfer. 2001;123:814-818.\par \par Witze PO. Diagnostics for the Measurement of Particulate Matter Emissions from Reciprocating Engines. In: The Fifth International Symposium on Diagnostics and Modeling of Combustion in Internal Combustion Engines (COMODIA). Nagoya; 2001.\par \par Choi D, Iwamuro M, Shima Y, Senda J, Fujimoto H. The effect of fuel-vapor concentration on the process of initial combustion and soot formation in a DI Diesel engine using LII and LIEF. SAE Technical Paper Series No. 2001-01-1255. 2001.\par \par Krishnan SS, Lin K-C, Faeth GM. Extinction and Scattering Properties of Soot Emitted from Buoyant Turbulent Diffusion Flames. Journal of Heat Transfer [Internet]. 2001;123:331-339.\par \par Allen MG, Upschulte BL, Sonnenfroh DM, Rawlins WT, Gmachl C, Capasso F, Hutchinson A, Sivco D, Cho A. Infrared Characterization of Particulate and Pollutant Emissions from Gas Turbine Combustors.  2001.\par \par Axelsson B, Collin R, Bengtsson P-E. Laser-induced incandescence for soot particle size and volume fraction measurements using on-line extinction calibration. Applied Physics B [Internet]. 2001;72:367\'e2??372.\par \par Smallwood GJ, Snelling DR, Neill SW, Liu F, Bachalo WD, G\'fclder \'d6L. Laser-Induced Incandescence Measurements of Particulate Matter Emissions in the Exhaust of a Diesel Engine. In: Proceedings of the Fifth International Symposium on Diagnostics and Modeling of Combustion in Internal Combustion Engines (COMODIA). Nagoya; 2001.\par \par Sorensen CM. Light Scattering by Fractal Aggregates: A Review. Aerosol Science and Technology. 2001;35:648-687.\par \par Snelling DR, Smallwood GJ, G\'fclder \'d6L. Method and apparatus for applying laser induced incandescence for the determination of particulate measurements.  [Internet]. 2001.\par \par Harris SJ, Maricq MM. Signature Size Distributions for Diesel and Gasoline Engine Particulate Matter. Journal of Aerosol Science. 2001;32:749-764.\par \par Jenkins TP, Hanson RK. Soot Pyrometry using Modulated Absorption/Emission. Combust. Flame. 2001;126:1669-1679.\par \par Jacobson MZ. Strong Radiative Heating Due to the Mixing State of Black Carbon in Atmospheric Aerosols. Nature [Internet]. 2001;409:695-697.\par \par Witze PO, Hochgreb S, Kayes D, Michelsen HA, Shaddix CR. Time-Resolved Laser-Induced Incandescence and Laser Elastic Scattering Measurements in a Propane Diffusion Flame. Applied Optics [Internet]. 2001;40:2443-2452.\par \par Smallwood GJ, Snelling DR, G\'fclder \'d6L, Clavel DJ, Gareau D, Sawchuk RA, Graham L. Transient Particulate Matter Measurements from the Exhaust of a Direct Injection Spark Ignition Automobile.  [Internet]. 2001.\par \par Snelling DR, Smallwood GJ, G\'fclder \'d6L. Absolute intensity measurements in laser induced incandescence.  [Internet]. 2000.\par \par Schraml S, Heimg\'e4rtner C, Will S, Leipertz A, Hemm A. Application of a New Soot Sensor for Exhaust Emission Control Based on Time Resolved Laser Induced Incandescence (TIRE-LII).  2000.\par \par Filippov AV, Rosner DE. Energy transfer between an aerosol particle and gas at high temperature ratios in the Knudsen transition regime. International Journal of Heat and Mass Transfer. 2000;43:127-138.\par \par Snelling DR, Liu F, Smallwood GJ, G\'fclder \'d6L. Evaluation of the nanoscale heat and mass transfer model of the laser-induced incandescence process for excitation intensity prediction. Proceedings of the 34th National Heat Transfer Conference. 2000:NHTC2000-12132.\par \par Snelling DR, Liu F, Smallwood GJ, G\'fclder \'d6L. Evaluation of the Nanoscale Heat and Mass Transfer Model of the Laser-Induced Incandescence: Prediction of the Excitation Intensity.  2000.\par \par Filippov AV, Zurita M, Rosner DE. Fractal-like aggregates: Relation between morphology and physical properties. Journal of Colloid and Interface Science [Internet]. 2000;229:261-273.\par \par Hansen J, Sato M, Reto R, Lacis A, Oinas V. Global Warming in the Twenty-First Century: An Alternative Scenario. Proceedings of the National Academy of Sciences [Internet]. 2000;97:9875-9880.\par \par Snelling DR, Smallwood GJ, Sawchuk RA, Neill SW, Gareau D, Clavel DJ, Chippior WL, Liu F, G\'fclder \'d6L, Bachalo WD. In-Situ Real-Time Characterization of Particulate Emissions from a Diesel Engine Exhaust by Laser-Induced Incandescence.  [Internet]. 2000.\par \par Axelsson B, Collin R, Bengtsson P-E. Laser-induced incandescence for soot particle size measurements in premixed flat flames. Applied Optics. 2000;39:3683-3690.\par \par Sch\'e4fer K, Heland J, Lister DH, Wilson CW, Howes RJ, Falk RS, Lindermeir E, Birk M, Wagner G, Haschberger P. Nonintrusive Optical Measurements of Aircraft Engine Exhaust Emissions and Comparison with Standard Intrusive Techniques. Applied Optics. 2000;39:441-454.\par \par Krishnan SS, Lin KC, Faeth GM. Optical properties in the visible of overfire soot in large buoyant turbulent diffusion flames. Journal of Heat Transfer Transactions of the ASME [Internet]. 2000;122:517-524.\par \par Schraml S, Will S, Leipertz A, Zens T, D?Alfonso N. Performance Characteristics of TIRE-LII Soot Diagnostics in Exhaust Gases of Diesel Engines.  2000:1935-1942.\par \par Cheng M-D. Real-Time Measurement of Trace Metals on Fine Particles by Laser-Induced Plasma Techniques. Fuel Processing Technology. 2000;65/66:219-229.\par \par Schraml S, Dankers S, Bader K, Will S, Leipertz A. Soot Temperature Measurements and Implications for Time-Resolved Laser-Induced Incandescence (TIRE-LII). Combustion and Flame. 2000;120:439-450.\par \par Snelling DR, Smallwood GJ, G\'fclder \'d6L, Bachalo WD, Sankar S. Soot Volume Fraction Characterization Using the Laser-Induced Incandescence Detection Method. In: Proceedings of the 10th International Symposium on Applications of Laser Techniques to Fluid Mechanics. Lisbon; 2000.\par \par Allouis C, D?Alessio A, Noviello C, Beretta F. Time resolved laser induced incandescence for soot and cenospheres measurements in oil flames. Combustion Science and Technology. 2000;153:51-63.\par \par Mulholland GW, Mountain RD. Coupled dipole calculation of extinction coefficient and polarization ratio for smoke agglomerates. Combust. Flame. 1999;119:56-68.\par \par Filippov AV, Markus MW, Roth P. 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