Inductively coupled plasma-mass spectrometry (ICP-MS) offers exceptional sensitivity and
multi-element capability for trace metal analysis but the formation of polyatomic ions
(particularly below m/z = 80) can cause, serious interferences. Such species can be
introduced via precursor atoms in atmospheric gases, the sample matrix or impurities in the
argon support gas. This thesis describes the development of a portfolio of analytical
methods coupled with ICP-MS detection for the determination of trace metals such as
manganese, cobalt, copper, nickel, zinc, mercury and lead in complex matrices such as sea
water. A literature review of coupled techniques is given in Chapter one.
Chapter two discusses the effect of sea water on the analytical performance of ICP-MS.
Initial studies were carried out using a single channel flow injection (FI) manifold and
included an investigation of the addition of nitrogen to the nebulizer gas flow of the ICPMS
for the reduction of the ArNa* polyatomic ion interference at m/z = 63 on the Cu
signal. This was followed by a multivariate simplex optimisation for the suppression of the
ArNa* polyatomic ion interference at m/z = 63 and non-spectroscopic interferences
affecting other masses in sea water, for the determination of Cu, Cr, Mn, Ni, Co, Zn and
Pb.
In Chapter three an on-line FI-ICP-MS matrix elimination method for the determination of
trace metals such as Mn, Co, Cu, Zn and Pb in sea water is discussed. The method involved
chelation of the analytes onto Chelex-100 or MetPac CC-1 iminodiacetate (IDA) .resin,
with the simultaneous removal of indirectly interfering matrix species, particularly Na and
CI ions. Results showing how the effects of the interferences were overcome, together with
validation of the method by the analysis of open ocean, coastal and estuarine certified
reference materials are reported.
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Chapter four compares FI approaches coupled with AFS, ICP-AES and ICP-MS detectors
for the determination of total mercury. Initial studies compared figures of merit for FI
(conventional pneumatic nebulization) and Fl-cold vapour generation (CVG) coupled with
ICP-AES and ICP-MS. Detection limits for total Hg were improved by developing simple
on- and off-line preconcentration procedures using a MetPac CC-1 micro-column
incorporated in a FI manifold vAth conventional pneumatic nebulization. An AFS detector
was then used in the development of a method for the determination of total mercury with
an on-line bromide/bromate oxidation step.
In chapter five an LC-ICP-MS method for the speciation of Hg in sea water samples is
described. The method involved the separation of mercury(II) chloride, methylmercury
chloride and ethylmercury chloride on a Cig ODS stationary phase with an ammonium
acetate/acetonitriIe/2-mercaptoethanol mobile phase. In order to achieve the necessary
detection limits required for the determination of mercury in real sea water samples (< 50
ng r^), an off-line preconcentration method using a dithiocarbamate resin was used.
Date of Award | 1994 |
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Original language | English |
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Awarding Institution | |
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THE DETERMINATION OF TRACE METALS IN SEA WATER USING ICP-MS
BLOXHAM, M. J. (Author). 1994
Student thesis: PhD