Following release to the environment, crude oil becomes subject to weathering processes
which remove the simple, volatile hydrocarbons leaving an unresolved complex mixture
(UCM) comprising the more environmentally persistent components. Aromatic UCMs
have been reported in a wide variety of environmental matrices. Recent studies indicate
such material, particularly monoaromatic hydrocarbons, is sufficiently bioavailable to
marine organisms (e. g. mussels) to elicit toxicological responses. However, little else is
known about the environmental fate and composition of petroleum-derived aromatic
UCMs. The overall aim of this work was to investigate aromatic UCMs with particular
emphasis on their biodegradability, water solubility and composition.
To assess persistence in the environment, an 'aromatic' UCM was isolated from Tia Juana
Pesado crude oil (Venezuela) and this UCM exposed to the hydrocarbon degrading
bacterium Pseudomonas fluorescens (Texaco). Five synthesised alkylcyclohexyltetralins
and an alkylcyclohexylnaphthalene, proposed previously as 'average' structures for some
aromatic UCM components, were also exposed under the same conditions. After 50 days,
biodegradation of the compounds had not exceeded 20%, the most resistant (-2%
biodegradation) being those with C3-C5 alkyl chains. These latter results were comparable
to those observed for the 'aromatic' UCM (-2%). Using North Sea oil or n-hexadecane as
co-substrates, the synthetic compounds were also exposed to a natural consortium of
bacteria to provide more environmentally realistic conditions. After 119 days the branched
chain C5 homologue (-60%) and the naphthalene (-12%) still remained, yet under these
severe conditions the components of the North Sea crude oil co-substrate were extensively
degraded with even the highly bioresistant pentacyclic hopanes exhibiting biodegradation.
Aqueous solutions of an 'aromatic' and 'monoaromatic' UCM were produced (at 25 'C)
using a generator column technique. These 'solubilised' UCM fractions may represent
UCM hydrocarbons which are bioavailable, and which are most toxic to aquatic organisms.
An altered UCM was clearly evident in the aqueous phase extracts, suggesting that many
of the compounds in the original aromatic and monoaromatic UCMs exhibited similar
physicochemical properties and mole fractions. However, higher molecular weight
hydrocarbons were absent from the generated 'solutions', indicating a solubility cut-off
point based predominantly on molecular weight. The molecular weight distribution
differed significantly for the 'solubilised' aromatic and monoaromatic UCMs, indicating
that Raoult's Law may describe a critical control in the dissolution of complex mixtures.
Comprehensive two-dimensional gas chromatography-time of flight-mass spectrometry
(GCxGC-ToF-MS) analysis was used to provide vastly increased separation power and
characterisation of a water 'soluble' monoaromatic UCM. Over 1200 compounds were
separated by the chromatography, of which about 500 had distinct mass spectra from the
ToF-MS analysis. A detailed characterisation of some of these monoaromatic UCM
hydrocarbons via comparison to mass spectra registered in the NIST library permitted the
identities of over 100 monoaromatic UCM components to be inferred. Compounds
identified include novel alkylated homologues of benzene, indene, indan, tetralin,
biphenyl, diphenylmethane and tetrahydrophenanthrene.
This study has shown that a UCM appeared to be comprised of the geochernically minor
isomers and analogues of known major crude oil constituents. This finding is extremely
important given that the narcotic toxicity of petroleum hydrocarbons is additive. As UCMs
often account for a large proportion of crude oil mass, these persistent residues may also
contribute significantly to the observed narcotic toxicity of crude oil.
Date of Award | 2004 |
---|
Original language | English |
---|
Awarding Institution | |
---|
Biodegradation, water solubility and characterisation studies of unresolved complex mixtures (UCMs) of aromatic hydrocarbons
Booth, A. M. (Author). 2004
Student thesis: PhD