2019
DOI: 10.1016/j.pecs.2019.05.003
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Soot formation in laminar counterflow flames

Abstract: Many practical soot-emitting combustion systems such as diesel and jet engines rely on diffusion flames for efficient and reliable operation. Efforts to mitigate soot emissions from these systems are dependent on fundamental understanding of the physicochemical pathways leading from fuel to soot in laminar diffusion flames. Existing diffusion flame−based soot studies focused primarily on overventilated coflow flame where the fuel gas (or vapor) issues from a cylindrical tube into a co-flowing oxidizer, and cou… Show more

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Cited by 359 publications
(130 citation statements)
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References 853 publications
(1,459 reference statements)
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“…In this work, computations are also based on a detailed physicochemical sectional model that has been developed and extensively tested by D'Anna and co-workers (see [39] and references therein). This model has been demonstrated to successfully predict soot formation for various simple fuels and flame configurations while supporting the latest experimental evidence of soot evolution in laminar flames [1,3,40]. A simplified version of this approach for ethylene, also called the NAPS soot model, has been recently presented in Refs.…”
Section: Napoli Sectional Model (Naps)supporting
confidence: 55%
“…In this work, computations are also based on a detailed physicochemical sectional model that has been developed and extensively tested by D'Anna and co-workers (see [39] and references therein). This model has been demonstrated to successfully predict soot formation for various simple fuels and flame configurations while supporting the latest experimental evidence of soot evolution in laminar flames [1,3,40]. A simplified version of this approach for ethylene, also called the NAPS soot model, has been recently presented in Refs.…”
Section: Napoli Sectional Model (Naps)supporting
confidence: 55%
“…An alternative would be to employ a quasi-one-dimensional counterflow diffusion flame (CDF). Due primarily to its simpler flow field and relative ease of modeling, CDF is particularly suitable for studying the fundamental chemistry of soot evolution [33][34][35][36], e.g., the fuel mixing effects on soot formation [37,38] as performed in this work. Additional benefits of CDF include its relevance to the laminar flamelet model [39], its resistance to buoyancydriven instability especially under high-pressure conditions [40], its capability to provide a sooting zone without interference from soot oxidation [41,42].…”
Section: Introductionmentioning
confidence: 99%
“…Recent reviews summarize important aspects of the particle-forming reaction sequences as well as methods to analyze the soot formation process [51 , 84 , 85 , [193] , [194] , [195] . Further work has described the physico-chemical characterization of particle emissions from engines [130 , 196 , 197] and of flame-sampled, aircraft-type soot with potential impact on cloud formation [198] .…”
Section: Selected Combustion Chemistry Advances – Overview and Recentmentioning
confidence: 99%