Amines have lower sooting tendencies than analogous alkanes, alcohols, and ethers

Amines have lower sooting tendencies than analogous alkanes, alcohols, and ethers

While the sooting tendencies of regular hydrocarbons, oxygenates, and complex fuel mixtures have been well-studied, far less research has been devoted to analyzing the influence of fuel-nitrogen on soot formation. The effect of nitrogen on soot formation becomes relevant for diesel fuels with nitrog...

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Veröffentlicht in:Combustion and flame 2021-05, Vol.227, p.335-345
Hauptverfasser: Montgomery, Matthew J., Zhu, Junqing, Pfefferle, Lisa D., McEnally, Charles S.
Format: Artikel
Sprache:eng
Schlagworte:
Additives
Alcohols
Alkanes
Amines
Biomass
Combustion chemistry
Diesel fuels
Ethers
Fuel mixtures
Hydrocarbons
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
Isomers
Line spectra
Nitrogen
Nonpremixed flame
Soot
Sooting tendency
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container_end_page 345
container_issue
container_start_page 335
container_title Combustion and flame
container_volume 227
creator Montgomery, Matthew J.
Zhu, Junqing
Pfefferle, Lisa D.
McEnally, Charles S.
description While the sooting tendencies of regular hydrocarbons, oxygenates, and complex fuel mixtures have been well-studied, far less research has been devoted to analyzing the influence of fuel-nitrogen on soot formation. The effect of nitrogen on soot formation becomes relevant for diesel fuels with nitrogen-containing additives, as well as biomass or biomass-derived fuels, which can contain up to 30% nitrogen-containing compounds by dry weight. To begin closing these gaps in the literature, the sooting tendencies of 14 C4 and C6 amines were measured. Sooting tendencies were quantified by re-scaling relative soot concentrations measured in fuel-doped methane flames into Yield Sooting Indices (YSI). The relative soot concentrations were measured with line-of-sight spectral radiance, and validation experiments confirmed that the presence of nitrogen in the test compounds did not interfere with this diagnostic. All of these amines had lower sooting tendencies than the structurally analogous hydrocarbons and oxygenates. The sooting tendencies of amine isomers with the same chemical formula varied significantly. Secondary amines with linear substituents were found to offer the lowest sooting propensity, while primary amines with branched substituents were observed to yield the largest sooting tendencies. The relationship between sooting propensity and chemical structure of the amines hints at the complex nature of soot formation, and highlights an interesting and unexplored area of combustion chemistry for further studies.
doi_str_mv 10.1016/j.combustflame.2021.01.016
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source Elsevier ScienceDirect Journals
subjects Additives
Alcohols
Alkanes
Amines
Biomass
Combustion chemistry
Diesel fuels
Ethers
Fuel mixtures
Hydrocarbons
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
Isomers
Line spectra
Nitrogen
Nonpremixed flame
Soot
Sooting tendency
title Amines have lower sooting tendencies than analogous alkanes, alcohols, and ethers
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