Unresolved Complex Mixtures (UCMs) of hydrocarbons are found in crude
and refined oils and in water, sediments and biota polluted with oils.
The concentrations of UCMs in oils are significant (e. g. >65% of the
aliphatic hydrocarbons in fresh Kuwait crude) and it is perhaps
surprising that virtually nothing is known about UCM composition. The
present study sought to redress this paucity of information in three
main ways:
First, following two recent studies of aliphatic UCMs, an investigation
of the composition of the "aromatic" UCM of Venezuelan Tia Juana Pesado
crude oil was made by spectroscopic (IR, NMR, MS) and oxidative (CrO3,
Ru04) methods. These showed that the UCM was, in fact, highly aliphatic.
The major compounds identified were alkyl substituted
naphthenoaromatics with one and two aromatic rings. Chemical oxidation
indicated that the alkyl branched side chains extended to at least
twenty three carbon atoms.
Second, an investigation into the origins of UCMs was made. The
products of hydrous pyrolysis of man-made (polythene) and biogenic
(cutan) polymers under conditions proposed previously to simulate
catagenesis, included, in the hydrocarbons, high proportions of UCMs
(50% - >70%). Hydrous pyrolysis of polythene produced a mixture of
saturated (56%) and olefinic (44%) hydrocarbons, whilst pyrolysis of
cutan produced hydrocarbon (aliphatic and aromatic; 30-75%) and nonhydrocarbon
(70-25%) fractions, both with >60% unresolved components.
Oxidative characterisation of these UCMs produced mainly n-acids with
somewhat similar results to those found when oil UCMs were oxidised.
However, the laboratory generated UCMs are not perfect oil UCM models
since some oil UCM oxidation products were not observed in the
laboratory models.
Finally, an attempt was made to release the geochemical information
contained within UCMs. Replicate oxidations of milligram quantities of
oil UCMs followed by quantitative GCMS characterisation and
multivariate statistical analysis of the resolved oxidation products
gave reproducible distributions with >80% similarity. Application of
this method to two oil spill incidents where the source oil was known
(Milford Haven and the Humber Estuary) gave good correlations between
sediment and source. In contrast analysis of Mersey Estuary sediments
contaminated with heavy asphaltic oil and of Sullom Voe sediments
contaminated with UCMs failed to show any correlation between the
sediments and the source oils. However, subsequent re-analysis of the
data excluding the major UCM oxidation products (n-carboxylic acids)
produced better correlations which indicated that the greatest
correlation potential for these UCMs was contained within the minor
oxidation products. A similar study of UCMs from two oil seeps from the
Siljan Ring region of Sweden failed to show any correlation with
potential source rocks, in agreement with biomarker data.
This study has extended present knowledge of UCM composition and
suggested a mechanism for UCM formation. Furthermore, quantitative and
statistical analysis of UCM oxidation products has been shown to be
useful for oil identification. There is still much to be learned about
UCMs and the subject should provide a fruitful area for further
research. Some possible approaches are suggested.
Parts of this work have been published [Revill et al. (1991), Organic
Geochemistry: Advances and Applications in Energy and the Natural
Environment, Manchester University Press
Date of Award | 1992 |
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Original language | English |
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Awarding Institution | |
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- Chemistry
- Organic Geochemistry
- Shale
- Bituminous coal
- Organic chemistry
Characterisation of unresolved complex mixtures of hydrocarbons by degradative methods
Revill, A. T. (Author). 1992
Student thesis: PhD