Sequential chemical extraction to fractionate metals in soils and sediments into different groups
reflecting their "leachability" has been widely employed to determine distribution of metals in different
physico-chemical phases. A large number of sequential extraction schemes have been reported, most
of them modifications of Tessier's extraction protocol. Although this method has been widely
accepted, it is important to highlight that sequential extraction procedures are often tedious and time
consuming and that they also suffer from a number of limitations, such as the problem of achieving
selective dissolution and the re-adsorption of trace metals during extraction.
The objective of this study was to develop, optimise, characterise and apply a novel sequential
extraction procedure for the evaluation of trace metal distribution in soils and sediments in order to
speed up the process, but more importantly to provide robust data for further aid the chemical
characterisation of such samples. The method developed used centrifugation to pass the extractant
solution (HNO3) at increasing concentrations, through the soil/sediment sample. The sequential
leachates were collected and analysed by ICP-AES for a suite of 18 analytes. The method then
utilised chemometrics in order to facilitate processing of the data.
Optimisation of the new extraction protocol was performed using an experimental design approach.
This was important since the method employed multi-elemental analysis to predict the composition of
the physico-chemical phases in a range of soils and sediments. The approach used for data
processing was again novel and was based on a simple product of matrices. However many statistical
and chemometric approaches are used throughout this thesis to aid both the design of the method
and the interpretation of the data obtained.
Once optimised, the methodology was evaluated using a range of reference materials and tentative
assignments were made in order to characterise the different physico-chemical phases in the soils by
comparison with previously obtained data following Tessier's protocol. Significant correlation was
obtained for the exchangeable fraction, the fraction associated with carbonates and the iron and
manganese oxides fraction. Hence the method proved to be effective in providing Important
information in terms of metal distribution in agreement with established procedures.
The method was then applied to the study of the effect of humic acids (HA) on trace metal distribution
in two different samples. Both samples were spiked with increasing amounts of humic acids and the
sequential extraction procedure was used to monitor the changes in metal distribution. Differences
when HA were added were found for most of the physico-chemical components in both samples. This
provided practical data to support the theoretical assumption that HA interact with the metals present
in the soil samples changing their distribution. Using the new method, an evaluation of the trace metal
distribution within the Arosa estuary (N.W. Spain) with respect to trace metal contamination was
performed.
Finally, an on-line automated multisequential extraction system was built "in-house", and coupled with
the ICP-AES instrument to allow the fast characterisation of soils and sediment samples. The new
system proved to be faster than the batch method and minimised the chance of sample mislabelling,
sample contamination etc. Good agreement between results obtained from the on-line method, the
batch method, and results using the Tessier scheme was obtained. The automated method clearly
offers great potential for a range of environmental pollution studies aiding the quick identication of
the physico-chemical components in geochemical samples.
Date of Award | 2004 |
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Original language | English |
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Awarding Institution | |
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NEW STRATEGIES TO DETERMINE THE DISTRIBUTION OF TRACE ELEMENTS IN SOILS AND SEDIMENTS
SANTAMARIA-FERNANDEZ, R. (Author). 2004
Student thesis: PhD