Nearly thirty C20, C25, and C30 highly branched isoprenoid (HBI)
hydrocarbons have been detected, sometimes in high concentrations, in
recent freshwater, estuarine, coastal and hypersaline sediments, and
water column particulate matter from numerous locations worldwide. The
parent structures have been proved but only a few of the double bond
positions have been established. The assignment of C21, C22 and C26
homologues and other C20 and C25 isomers, remains tentative. A wide body
of evidence suggests that the compounds are biogenic in origin, with
algae and possibly bacteria the most likely source organisms. A few of
the compounds have been identified in field samples of algae but none
have been reported in laboratory cultured biota.
The alkenes with more than two double bonds appear to be rapidly
removed from the hydrocarbon fraction in most sediments, whereas the
alkanes and monoenes seem to be more resistant to biodegradation and
hence occur in some more ancient sediments and oils. There is evidence
that some of the alkenes react rapidly with sulphur to form either S-containing HBI heterocycles or become bound within macromolecular
aggregates both found in sediments and some oils. The compounds, both
as hydrocarbons and S-containing analogues, may prove useful
environmental indicators once the sources and exact structures of more
of them have been established.
In the literature the structural elucidation of C25 and C30
alkenes has been based mainly on the analysis of their hydrogenation
products. However, some authors concluded that the alkenes are cyclic
since some could not be fully hydrogenated. The structure of a C25 HBI
diene was proven to be a cyclic by hydrogenation studies and GC and GCMS
analyses which showed the HBI compound to be fully saturated.
The isolation and characterisation of synthetic alkenes resulted
in the assignment, or partial assignment, of structures to four C20, six
C25 and four C30 monoenes. The formation of novel monoenes via
isomerisation reactions has also been achieved. The compounds form a
valuable database of chromatographic and spectroscopic information for
the assignment of sedimentary alkenes but the importance of isolation
and micro-ozonolysis has been emphasised.
Synthetic HBI alkenes were used to assign structures and partial
structures to naturally occurring HBI hydrocarbons in three sediments.
Other monoenes (both with methylene double bonds) were isolated from
the sediments and characterised using spectroscopic and micro-ozonolysis data.
The widespread occurrence of C20 and C23 HBI hydrocarbons in Tamar
sediments and associated algae (macrophytes and diatoms), the large
variation in isotopic composition evident for the C20 monoene, and the
seasonal sedimentary distribution all suggest two possible sources for
the HBI hydrocarbons; microalgae and/or heterotrophic bacteria.
Investigation of the distribution of hydrocarbons from the Peru
upwelling area confirmed the rapid decrease in concentration of C25 HBI
alkenes with depth. A mixture of HBI monoenes was successfully
incorporated into melanoidins but not detected in the humic acid
pyrolysate which implied that incorporation of HBI alkenes into
accreting humic substances was not a major mechanism of diagenesis of
HBI alkenes.
This study has extended present knowledge of the structures of
HBI monoenes and has suggested two possible biological sources. There
is still much to be learned about HBI polyenes and the subject is
proving to be a fruitful area for further research into biomarker
potential. Some possible future approaches are suggested.
Date of Award | 1992 |
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Original language | English |
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Awarding Institution | |
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ORIGINS AND SHORT-TERM SEDIMENTARY FATE OF GLOBALLY DISTRIBUTED BIOLOGICAL MARKER HYDROCARBONS
HIRD, S. J. (Author). 1992
Student thesis: PhD