Analysis and speciation of selenium ions in mine environments |
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| Authors: | S. Sharmasarkar G. F. Vance F. Cassel-Sharmasarkar |
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| Affiliation: | (1) Department of Plant, Soil and Insect Sciences, University of Wyoming, Laramie, WY 82071, USA, US |
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| Abstract: | Aqueous extracts of five mine soil samples and a set of selenite (SeO3 2–)–selenate (SeO4 2–) solutions (0.5, 1, 5, 10 and 25 mg/l) were speciated using atomic absorption spectroscopy with hydride generation (AAS-HG) and ion chromatography (IC) to compare these methods for Se speciation. In another experiment, a SeO3 2––SeO4 2––SO4 2– solution (25 mg/l) was reacted with CaO, MgO, MnO2, CuO, La2O3, and WO3 to evaluate the relative distribution of the Se species and SO4 2– in the SORB (sorbed ions that were desorbed by NaOH), SOLN (equilibrium concentrations), CMPX (irreversibly sorbed and neutral ion pair complexes) fractions. The AAS-HG method was capable of analyzing Se as low as 0.002 mg/l, which was below the detection limit of IC. High concentration of SO4 2– affected the chromatographic Se speciation either by shifting or overlapping Se peaks, in which AAS-HG was more useful. However, IC was capable of speciating aqueous SeO3 2––SeO4 2– directly without any sample pretreatment, whereas AAS-HG measured SeO3 2–+SeO4 2–, and SeO3 2– in separate runs and SeO4 2– was calculated from the difference, i.e., spectrophotometric speciation was an indirect method. For both Se species, AAS-HG and IC data were comparable within detection standard deviations. Ratios of different Se species at measured soil pH and pe indicated that SeO3 2– or SeO4 2– would be the dominant Se species; the p(SeO4 2–/SeO3 2–) values further suggested SeO4 2– would be the major solution species. Except for CaO and MgO treatments, the %SeO3 2– in the SORB fraction was ≥%SeO4 2–. In the SOLN fraction %SeO4 2– was ≥%SeO3 2– for all oxides but CaO, whereas in the CMPX fraction this order was observed for only CaO and MnO2. The %SeO3 2– was highest in the SOLN fraction for all oxides but MgO and La2O3 for these two oxides SeO3 2– dominated in CMPX and SORB fractions, respectively. The SOLN fraction also contained the highest %SeO4 2– for all oxides but MgO which retained SeO4 2– primarily in the SORB fraction. The %SeO3 2– and %SeO4 2– in the CMPX fraction were highest for MgO, thus, suggesting a possible formation of MgSeO3 0 and MgSeO4 0. A similar trend of SORB %SO4 2– and SORB %SeO4 2– was attributed to the analogous adsorption mechanisms (outer-sphere complexation). For all oxides but MgO, %SO4 2– was <%SeO4 2– in the SOLN fraction and ≥%SeO4 2– in the CMPX fraction. Comparative ionic distributions provide an overall picture of the relative abundance of different Se species in various fractions associated with different oxides present in micro- and macrolevels in soils and geological materials. Received: 27 December 1995 · Accepted: 29 April 1997 |
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| Keywords: | Spectroscopy Chromatography Species Selenium |
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