A flow detector based on square-wave polarography at the dropping mercury electrode

Abstract Square-wave polarography (s.w.p.) at the DME has been adapted for detection in various analytical flow systems. The combination of high sensitivity with rapid potential scan rates results in detector characteristics significantly superior to those previously reported for techniques involving constant applied potential. In an automated flow system for the analysis of discrete samples, s.w.p. allows sensitive and reproducible multi-component sample analysis, at a sampling rate of 22.5 samples per hour (at a 1:1 sample/wash ratio and with relatively low sample volumes). The electrochemical selectivity of the detector may be exploited for monitoring Chromatographic column effluents, in cases where the chromatographic separation is incomplete: species eluted simultaneously but having different reduction potentials can be determined with satisfactory sensitivity. The in-situ monitoring system based on s.w.p. allows rapid simultaneous determinations (~ 300 per hour) of a number of contaminants present at the sub-ppm level; because of its long-term stability and reproducibility, it seems well suited for continuous contaminant control.

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