APPLICATION OF FLOW-INJECTION INDUCTIVELY-COUPLED PLASMA-MASS SPECTROMETRY TO THE SIMULTANEOUS DETERMINATION OF ARSENIC, ANTIMONY, TIN, BISMUTH, SELENIUM AND TELLURIUM IN STEELS
Ag. Coedo et Mt. Dorado, APPLICATION OF FLOW-INJECTION INDUCTIVELY-COUPLED PLASMA-MASS SPECTROMETRY TO THE SIMULTANEOUS DETERMINATION OF ARSENIC, ANTIMONY, TIN, BISMUTH, SELENIUM AND TELLURIUM IN STEELS, Journal of analytical atomic spectrometry, 9(10), 1994, pp. 1111-1115
Flow injection inductively coupled plasma mass spectrometry (FI-ICP-MS
) was used for the simultaneous determination of arsenic, antimony, ti
n, bismuth, selenium and tellurium in steels from high-concentration d
issolved solid solutions. To dissolve the samples a microwave digestio
n system was applied to minimize the sample preparation time, the amou
nts of reagents and the risk of contamination. Two internal standards
(Be and Rh), with ionization potentials closest to the highest and the
lowest potentials of the analyte elements, were used for quantitative
measurements. The flow injection and inductively coupled plasma opera
ting parameters were optimized with respect to signal peak height and
peak area intensities, stability and matrix effects. The detection lim
its for flow injection from solutions with high concentrations of diss
olved solid [0.5% m/v Fe almost-equal-to 2% Fe(NO3)3] were 4-6 times b
etter than those for continuous-flow sample aspiration of a 0.05% Fe m
atrix solution [approximately 0.2% Fe(NO3)3]. The relative standard de
viations of peak areas calculated from four replicate injections of a
20 mug l-1 multi-element-spiked 0.5% m/v Fe solution varied between 1.
7 and 3.0%. Acid multi-element standard calibration solutions were use
d for the net ratio measurements. Standard reference steel materials,
Series 361-365 from NIST and ECRM 088 and 097 from BAS, were analysed
to demonstrate the accuracy of the proposed method.