The form of trace metals, so called "speciation", is of vital
importance in many fields, e.g., toxicology and environmental
monitoring. A promising analytical approach to speciation studies is
the coupling of chromatography, for species separation, to the
selectivity and sensitivity of atomic spectroscopy for detection. The
suitability of such couplings are discussed and the applications of
both gas and liquid chromatography reviewed.
The success of coupled gas chromatography (GC) - flame atomic
absorption spectroscopy (FAAS) is demonstrated for the unequivocal
identification of petrol residues in forensic applications. The
advantages and disadvantages of this technique are discussed with
reference to both sufficiently volatile and non-volatile compounds.
The advantages of high performance liquid chromatography (HPLC) for
many studies are discussed. As coupled HPLC-ETA-AAS (electrothermal
atomisation - atomic absorption spectroscopy) suffers from non-continuous
detection, coupling is difficult and chromatography
constrained. In contrast, a simple HPLC-FAAS coupling utilising pulse
nebulisation and a modified atom cell was developed which produced
continuous chromatograms in real time. Application of this system to
determining tributyltin (TBT+) compounds in seawater yielded a
detection limit of 200 ng ml ˉ¹.
A directly coupled system utilising continuous flow hydride generation
is described, and for species with non-volatile hydrides, on-line UV
photolysis was incorporated. The effects of various parameters on
analytical performance are discussed, and applications to real samples
given. Detection limits for TBT+ were improved 100 fold.
A novel sample transport interface using rotating platinum wire
spirals controlled by a microprocessor, utilised the attractive
features of flame atomisers but sample introduction via the nebuliser
was avoided. Applications are reported using both minibore HPLC for
alkyllead speciation and fast protein liquid chromatography for
speciating zinc in human serum.
Applications of the above techniques for determining organometallic
species of Pb, As, Sn, Cu, Zn and Cd are described and possible future
work discussed.
Date of Award | 1985 |
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Original language | English |
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Awarding Institution | |
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DIRECTLY-COUPLED CHROMATOGRAPHY - ANALYTICAL ATOMIC SPECTROSCOPY FOR TRACE METAL SPECIATION
Hill, S. (Author). 1985
Student thesis: PhD