Emission limits for diesel engine exhaust pollutants are being continually reduced in
line with increasingly stringent emissions legislation. Essential to the task of reducing
diesel exhaust emissions is an understanding of the origin of the exhaust pollutants.
This research has investigated the origin of a group of compounds, polycyclic
aromatic hydrocarbons (PAH), in diesel exhaust emissions using 14C-radiotracer
techniques developed specifically to investigate the origin of the organic components
in diesel emissions. The use of radiotracers in this research has enabled both the
extent to which individual PAH survive combustion and the extent to which PAH are
pyrosynthesized during combustion to be measured accurately. No other diesel
emissions research technique has yielded information which is so unequivocal.
Radio-chromatographic techniques were developed specifically for the identification
and quantification of radioactive species present in diesel emissions resulting from the
combustion of a single 14C-radiolabelled precursor. Radio-high performance liquid
chromatography (radio-HPLC) was the main technique used and was applicable as
both a tool for sample fractionation and for analytical measurement. Radio-gas
chromatographic techniques (radio-GC) were also developed and applied to the
identification of radioactive species in the exhaust emissions.
Diesel exhaust samples were collected from a 2L direct injection Perkins Prima diesel
engine using a novel exhaust sampling device, the Total Exhaust Solvent Stripping
Apparatus (TESSA) devised previously to sample organic species from automobile
exhausts. Diesel combustion experiments were performed on three 14C-radiolabelled
PAH, fluorene, pyrene and benzo[α]pyrene (B[α]P), and 14C-n-hexadecane. These
were spiked into the diesel fuel and were combusted in the Prima Engine. The extent
of survival was 0.04% for B[α]P, 0.17% for pyrene and 0.87% for fluorene. The
amount of each PAH in the exhaust emissions derived from pyrosynthetic sources
ranged from <20% for B[α]P, to 26.5% for fluorene and 71% for pyrene.
The extent to which individual PAH survive the diesel combustion process was
correlated with the molecular orbital distribution of the molecule, and especially the
energy levels of the lowest unoccupied molecular orbital (LUMO). It is concluded
that the relationship between PAH survival and PAH molecular orbitals (MOs) is
owing to the kinetics of combustion reactions and the chemical reactivity of the P AH.
The extent to which individual PAH molecules are formed during combustion varies
considerably. From the limited number of experiments performed in the current
research it has not been possible to determine the mechanisms responsible for the
formation of these PAH during combustion. Mass balance calculations have
demonstrated that the degree of pyrosynthesis of the parent PAH molecules
investigated in this research may be accounted for by comparatively low rates of
dealkylation of alkyl-substituted derivatives present in diesel fuel.
The importance of dealkylation reactions during diesel combustion, was investigated
by combusting a low aromatic fuel spiked with a non-radiolabelled alkyl-PAH, 2- and
3-ethylphenanthrene (2- and 3-EtPa), which were synthesized for this purpose. The 2
and 3-EtPa isomers were recovered in yields of 0.35% and 0.3% respectively. No
dealkylation of the EtPa was detected. A statistically significant increase in the
emissions of 3-methylphenanthrene (3-MePa) was detected and was equivalent to a
conversion rate of 0.0004% of the EtPa spike. It is proposed that the ease with
which individual alkyl-PAH isomers are dealkylated varies for specific isomers, and is
dependent on the position of the alkyl-substituent on the aromatic nucleus. The
major product from the combustion of the EtPa was vinylphenanthrene (ViPa) which
produced in a yield equivalent to a conversion of 0.01% of the EtPa spike.
Radiotracer experiments with 14C-n-hexadecane were performed to investigate the
origin of the aliphatic component of diesel emissions. The extent of hexadecane
survival was 0.35%. Approximately two thirds of the hexadecane in the emissions
was derived from pyrosynthetic sources. The most probable source of the
pyrosynthesized hexadecane in the emissions was 'thermal cracking of higher
molecular weight aliphatic species in diesel fuel during the combustion process. This
process may account for a significant proportion of lower molecular weight n-alkanes
emitted in diesel emissions.
Date of Award | 1995 |
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Original language | English |
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Awarding Institution | |
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The Origin of Polycyclic Aromatic Hydrocarbons in Diesel Exhaust Emissions
Tancell, P. J. (Author). 1995
Student thesis: PhD