Identification of the heteroatom (nitrogen, sulphur, and oxygen; NSO)-containing
compounds of petroleum is of key importance when considering industrial and
environmental issues associated with crude oil production. The inherent molecular
complexity of petroleum is such that detailed compositional investigations must ideally
be preceded by some form of pre-fractionation. However, the more commonly performed
methods of crude oil fractionation are often insufficient in the extent to which they
separate oils, not allowing defined “molecular” fractions to be obtained and thus
hindering more detailed investigations. The following work therefore focused on the
development of chromatographic methods to aid in the characterisation of NSO
compounds present within crude oils.
A novel solid phase extraction (SPE) procedure was developed utilising both ion
exchange and adsorption chromatography. The method enabled fractions broadly defined
as ‘saturated’ hydrocarbons; ‘aromatic’ hydrocarbons; basic nitrogen compounds;
naphthenic acids; phenols and other oxygen-containing species; carbazoles; sulfoxides;
and thiophenes, to be isolated reproducibly and quantitatively from relatively small crude
oil samples (~ 0.5 g). Assessment of method selectivity with a suite of ‘model’
compounds showed that the resulting fractions were quite well defined, with classes of
‘model’ compounds being isolated within discrete fractions. Application to five crude oils
of widely varying properties and origins, such as API gravity (12.1−38.3°), demonstrated
the potential for the wide-ranging use of the method. Sample recoveries were high
(77−98%) with simple evaporative losses accounting for the majority of sample loss.
Repeatability was also high, demonstrated by triplicate analyses of ‘model’ compound
mixtures, oils spiked with ‘model’ compounds and oils alone.
Subsequent, more detailed, analysis of the fractions using multidimensional gas
chromatography-mass spectrometry (GC×GC-MS) and liquid chromatography-highresolution
accurate mass-mass spectrometry (LC-HRAM-MS) showed the advantages of
the new isolation method. For example, alkylated series (C1-5) of quinolines, carbazoles,
fluorenones, dibenzothiophenes and xanthones were identified within their predicted
fractions. Furthermore, comparison of mass spectra obtained from GC×GC-MS analyses
with reference spectra resulted in the tentative identification of compounds hitherto not
previously reported in crude oils, again illustrating the advantage of the isolation method.
Novel series of thioxanthones, tocopherols (E vitamins) and terpenoidal sulfoxides and
ketones were assigned within the isolated fractions.
Following the successful evaluation of the method, the scheme was subsequently
employed to investigate the effects of changing geochemical parameters on the
composition of isolated NSO-containing compounds. For example, studies of NSO
fractions from series of crude oils at different stages of thermal maturity or of
biodegradation, led to the identification of a number of potential new molecular markers
within the basic-nitrogen and ketone fractions. This work shows clear potential for the
developed NSO isolation method to be used in further compositional studies as a tool to
aid in geochemical investigations.
Date of Award | 2018 |
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Original language | English |
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Awarding Institution | |
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Supervisor | Steven Rowland (Other Supervisor) |
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- Geochemistry
- Petrochemistry
- Analytical Chemistry
The Separation of the Polar Constituents of Petroleum
Robson, W. (Author). 2018
Student thesis: PhD