Molecular Characterization of the Gas–Particle Interface of Soot Sampled from a Diesel Engine Using a Titration Method

Surface functional groups of two different types of combustion aerosols, a conventional diesel (EN 590) and a hydrotreated vegetable oil (HVO) soot, have been investigated using heterogeneous chemistry (i.e., gas–particle surface reactions). A commercial sample of amorphous carbon (Printex XE2-B) wa...

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Bibliographic Details
Published in:Environmental science & technology 2016-03, Vol.50 (6), p.2946-2955
Main Authors: Tapia, A, Salgado, M. S, Martín, María Pilar, Lapuerta, M, Rodríguez-Fernández, J, Rossi, M. J, Cabañas, B
Format: Article
Language:English
Subjects:
Aerosols
Aerosols - analysis
Air Pollutants - chemistry
Diesel engines
Experiments
Gases
Kinetics
Molecules
Plant Oils - chemistry
Soot - chemistry
Vehicle Emissions - analysis
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Summary:Surface functional groups of two different types of combustion aerosols, a conventional diesel (EN 590) and a hydrotreated vegetable oil (HVO) soot, have been investigated using heterogeneous chemistry (i.e., gas–particle surface reactions). A commercial sample of amorphous carbon (Printex XE2-B) was analyzed as a reference substrate. A Knudsen flow reactor was used to carry out the experiments under molecular flow conditions. The selected gases for the titration experiments were: N­(CH3)3 for the identification of acidic sites, NH2OH for the presence of carbonyl groups, CF3COOH and HCl for basic sites of different strength, and O3 and NO2 for reducing groups. Reactivity with N­(CH3)3 indicates a lower density of acidic functionalities for Printex XE2-B in relation to diesel and HVO soot. Results for NH2OH experiments indicates that commercial amorphous carbon exhibits a lower abundance of available carbonyl groups at the interface compared to the results from diesel and HVO soot, the latter being the one with the largest abundance of carbonyl functions. Reactions with acids indicate the presence of weak basic oxides on the particle surface that preferentially interact with the strong acid CF3COOH. Finally, reactions with O3 and NO2 reveal that diesel and especially HVO have a significantly higher reactivity with both oxidizers compared to that of Printex XE2-B because they have more reducing sites by roughly a factor of 10 and 30, respectively. The kinetics of titration reactions have also been investigated.
ISSN:0013-936X
1520-5851
DOI:10.1021/acs.est.5b05531