Abstract

Schwertmannite (SHM) is a naturally occurring mineral that has been shown to effectively scavenge oxyanions from contaminated water. In this study, Fourier-transform infrared spectroscopy and X-ray absorption spectroscopy techniques in combination with wet-chemical techniques were used to study the competitive sorption of Se(IV) and Se(VI) at pH 3. The experiments were conducted with three types of schwertmannite obtained from oxidative synthesis, biogenic synthesis and high-pressure compaction at different initial Se concentrations and mixing ratios for 48 h and 56 days, respectively. A threshold value for the uptake mechanisms was identified, which reflects the amount of easily exchangeable sulphate (~0.5 mmol/g). At adsorbate concentrations below this threshold, an inner-sphere corner-sharing bidentate binuclear complex forms upon exchange with sulphate. At higher concentrations, both oxyanions become bound to SHM through co-occurrence of mainly inner-sphere and partly outer-sphere corner-sharing bidentate binuclear complexes with Fe(III) containing surface sites. Single species experiments clearly indicate a higher affinity of SHM for Se(IV). However, in mixed species experiments, competitive sorption occurs with equal or even preferential uptake of Se(VI) at concentrations much lower than the threshold value, presumably due to geometrical similarity between selenate and sulphate, and increasing preference for Se(IV) at high Se concentrations.

Highlights

  • Selenium (Se) is an essential micronutrient for humans and animals

  • This study investigates the effect of the loading concentration of Se(IV) and Se(VI), their mixing ratio, as well as the effect of aging on partitioning of these species under acidic conditions into schwertmannite using Se K-edge X-ray absorption spectroscopy near edge structure (XANES) and extended X-ray absorption fine structure (EXAFS) in combination with FTIR

  • Our results show that a threshold value for the uptake mechanism exists, which is the amount of exchangeable sulphate (~0.5 mmol/g)

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Summary

Introduction

Se exists in different forms but the predominant ones are the oxyanionic species selenite (Se(IV), SeO32−) and selenate (Se(VI), SeO42−), which are among the list of oxyanions that cause severe contamination of natural waters and aquatic environments due to their toxicity, bioavailability and mobility [1]. The occurrence of these species is typically controlled by pH and redox conditions with alkaline and well oxidized environments favouring the predominance of Se(VI) [2]. Selenium (Se) pollution and its control has gained increased attention and a variety of physical, chemical and biological technologies to remove Se from water have been investigated, such as nanofiltration, reverse osmosis, algae treatment and adsorption [4]

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