RESUL TS AND DISCUSSIONFigur e 2 sh

RESUL TS AND DISCUSSION
Figur e 2 shows the response characteristics of the mer cury-coated GC electrode to mixtures of seven
differ ent concentrations of cadmium and lead ions in 0.1M HNO3 solution when potentials wer e
applied from -0.8 V to -0.3 V with a square-wave positive going scan. The electrode displayed
well-defined, sharp (nearly symmetrical) and separated peaks for cadmium and lead ions at applied
potentials of about -0.6 and -0.45 V , respectively . The peak currents measured with the GC electrode
wer e linearly proportional to the cadmium and lead concentrations in the range of 1 to 200 ppb. In
addition, ther e wer e strong linear relationships between Cd or Pb concentrations and peak currents (r
2
> 0.95), indicating that both of the CdandPb ions could be quantitatively measured measurements.
Figur e 3 illustrates square-wave stripping voltammograms for cadmium and lead, at concentration
levels of 1 to 200 ppb in 0.1M HNO3 solutions, at the bismuth film electrode. As compared to the
mer cury electrode, the shapes of electric current for varying the applied potentials at the bismuth
electrode wer e not symmetrical and the potentials causing peak currents wer e inconsistent. Such
problems might be related to the non-homogeneous distribution of the bismuth on the GC electrode
with varying sizes of the particles (Fig. 4). However, as found in the mercur y film electrode tests, the
bismuth-coated electrodes showed strong linear relationships between concentrations of Cd and Pb
ranging from 1 to 200 ppb,and peak currents measuredat around -0.7and -0.45 V for Cdand Pb ions,
respectively . Therefor e, it was concluded that bismuth could bea viable candidate for detecting Cdand
Pb in the 0.1M HNO3 solutions.