Selenium Contamination in Water. Группа авторов

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Selenium Contamination in Water - Группа авторов


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and CSe2) and gaseous (H2Se and SeF4) state (Butterman and Brown 2004). Owing to its varied oxidation states it forms different type of compounds with sulfur (selenium sulfide (Se2S2) and polysulfides), oxygen (selenate, SeO4−− and selenite SeO3−−), hydrogen selenide (H2Se), and some organometalic compounds with methyl such as dimethylselenide ((CH3)2Se), dimethyl selenone ((CH3)2SeO2), and dimethyl diselenide ((CH3)2Se2) that are widely distributed in biogeologic forms. On substitution of sulfur it forms selenocysteine, selenocystine, and selenomethionine with amino acids (Chabroullet (2007); Losi and Frankenberger (1997); Haygarth (1994); Fernández‐Martínez and Charlet 2009). Therefore, it is clear that a range of inorganic and organic molecular forms of Se are present in environmental material such as rocks, soils, the aquatic system, and in air.

      Bioavailability of Se species is mainly governed by the distribution of Se in particle (insoluble Se species) and dissolved phases. Selenate (SeO42−) and selenite (SeO32−) are the soluble inorganic forms of Se, among which selenate (SeO42−) is considered the most soluble Se form (~90–95% of soluble se in arid agriculture water) (Masscheleyn et al. 1990). However, Se(0) and Se(‐II) are usually insoluble until available in suspended form. A quantitative relation between particulate and soluble Se species can be depicted in terms of distribution coefficient (Kd = Se per unit mass particulate material/Se per unit volume water, in units of equivalent) (IAEA 1994). This is frequently used to calculate the sorption behavior of Se in soil. Thus, accumulation of Se in animals is mainly in the particulate form as compared with that of the amount taken up from water (Luoma et al. 1992). Biogeochemical transformation reactions govern the Se concentration based on interaction between soluble and particle Se species. Concentration of Se in the food web is dependent on efficiency of transformation from dissolved to particulate Se by microorganism and determined in terms of μg of Se/g. Nakamaru et al. (2005) have reported that Kd of Se is 600–800 l/kg for Japanese agricultural andosols.

      For transportation of selenium aquatic bodies play important role (Cutter and Bruland 1984), therefore it is important to know the species present in the aqueous medium.

Shematic illustration of E-pH diagram of selenium in soils.

      (Source: adapted from Mayland et al. 1989 with permission from John Wiley and Sons).

      In combination with other naturally occurring ecological conditions, organic matters (OM) have also play a vital role. It has been reported that Se interacts with OM in soil and aquatic environments (Abrams et al. 1990; Zhang and Moore 1996). The distribution coefficient (Kd) for Se‐OM is 1800 l/kg which is twice that for Se to soil clay. This association of Se‐OM governs the mobility of Se species by complexation process (Filella and Town 2003). In soil and water the high heterogeneity of OM (Sutton and Sposito 2005) makes it more complex to study the properties of OM because of the occurrence of higher OM content in top soil; Se concentration is high in surface soil as compared to deeper soil layers (Zhang and Moore 1996).

      Ferri and Sangiorgio (2001) have studied the interaction of selenite with natural polysaccharides of different molecular weight. The studies revealed that the charge on organic species doesn't affect the formation constants but its strength is dependent on the structure of the complex. It has been reported that Se binds well with OM in acidic soils (Christensen et al. 1989; Gustafsson and Johnson 1992). Interaction with humic and fulvic acids has been studied and correlated with animal (Wang et al. 1996) and plant uptake (Kang et al. 1991; Zhang and Moore 1996). The interaction of Se species with fulvic acid (soluble) is more bioavailable than humic acid (suspended particulate) (Qin et al. 2012). This can be explained by the retention of negatively charged oxyanions by the OM that immobilizes the Se species in anoxic conditions. The study of interaction of selenium oxyanions and humic acid has been carried out in by Bruggeman et al. (2005, 2007). The interaction of inorganic Se with humic acid as well as with plants and microbial processes may immobilize Se (Tolu et al. 2014) and make them less bioavailable. In the presence of reducing phase (e.g. FeS2), selenate is expected to reduce to selenite which is removed by precipitation (Bruggeman et al. 2005). This elemental Se can be further altered to ferroselite


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