2016
DOI: 10.1021/acs.energyfuels.6b00322
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Quantification of the Fraction of Particulate Matter Derived from a Range of 13C-Labeled Fuels Blended into Heptane, Studied in a Diesel Engine and Tube Reactor

Abstract: This paper presents the results of an experimental study that was carried out to determine the conversion rates to particulate matter (PM) of several liquid fuel hydrocarbon molecules and specific carbon atoms within those molecules. The fuels investigated (ethanol, n-propanol, i-propanol, acetone, and toluene) were blended in binary mixtures with n-heptane to a level of 10 mol percent. The contribution of the additive molecules to PM was quantified using a carbon-13 (13C) labeling experiment, in which the fue… Show more

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Cited by 7 publications
(8 citation statements)
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“…Eveleigh et al 112 carried out a similar isotope-labelling experiment and blended a number of alcohols (ethanol, n- propanol and isopropanol) and a ketone (acetone) into binary mixtures with n -heptane to a level of 10% (molar concentration), which were combusted in a diesel engine and a flow reactor. Similar results were obtained in both systems, where in the case of the alcohols, the carbon atoms bonded to the hydroxyl groups contributed to soot formation in all cases, but to a reduced extent compared with the average carbon atom.…”
Section: Influences Of the Fuel Molecular Structure On Engine Exhaustmentioning
confidence: 99%
“…Eveleigh et al 112 carried out a similar isotope-labelling experiment and blended a number of alcohols (ethanol, n- propanol and isopropanol) and a ketone (acetone) into binary mixtures with n -heptane to a level of 10% (molar concentration), which were combusted in a diesel engine and a flow reactor. Similar results were obtained in both systems, where in the case of the alcohols, the carbon atoms bonded to the hydroxyl groups contributed to soot formation in all cases, but to a reduced extent compared with the average carbon atom.…”
Section: Influences Of the Fuel Molecular Structure On Engine Exhaustmentioning
confidence: 99%
“…Using the same 13 C technique, tracer studies were also carried out using both the tube reactor and a direct injection compression ignition engine (Eveleigh et al, 2015(Eveleigh et al, , 2016. In the first study, the engine was fueled with labeled single-component oxygenated fuels, a free fatty acid (oleic acid), and a fatty acid methyl ester (methyl oleate; Eveleigh et al, 2015).…”
Section: Isotope Studies Of Soot and Pm Formationmentioning
confidence: 99%
“…The double bonded carbon atoms in oleic acid did contribute to PM formation, but at a similar rate as the average alkyl chain carbon atom; suggesting no extra contribution of the double bonded carbon atoms to particulate formation. In the second study, a range of molecules (ethanol, n-and i-propanol, acetone, and toluene) were blended in binary mixtures with n-heptane (to 10 mol%) and the contribution of individual carbon atoms to PM was assessed (Eveleigh et al, 2016). One of the interesting results from this study was that in the engine, the aromatic toluene component of the binary mixture contributed disproportionately to the formation of PM, which was consistent with the result of Sorek and Anderson (1985) obtained in a diffusion flame (discussed above).…”
Section: Isotope Studies Of Soot and Pm Formationmentioning
confidence: 99%
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“…Unlike FAME, they do not have any oxygen in their molecular structures. The presence of oxygen in a fuel has two main advantages; there is a reduction of carbon content in the fuel, thus, soot formation (emission) of the fuel is significantly reduced, 28,29 and secondly, aircraft's engine particulate matter emissions fall by almost 40 % when jet fuel was blended with oxygenated fuels. 30 A lot more effort in research is still needed in this field.…”
Section: Introductionmentioning
confidence: 99%