Selenium Contamination in Water. Группа авторов

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Selenium Contamination in Water - Группа авторов


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and biological redox reactions beneath the soil, and mineral formations. The occurrence of Se in the soil or in water sources depends mainly on the climate, topography, and parental material (El‐Ramady et al. 2014b). Minerals such as sulfide minerals are associated with selenite‐ and selenide‐containing rocks. The erosion of these rocks is responsible for the occurrence of Se in soils in the form of elemental Se, for instance selenite salts, ferric selenite, or in its organic form (Malisa 2001). The anionic forms of Se, i.e. selenite and selenate, are highly soluble, bio‐available, mobile, and toxic above certain limits. Decomposition of plant which accumulate Se are the sources of organic forms of Se.

      The available level of Se in soil is mainly dependent on the texture of soil, rainfall, the kind of soil, and the concentration of organic matter. The lowest concentration of Se is obtained in sandy soils while the highest is in organic and calcareous soil. The major Se‐controlling factors in the soil are Eh and pH whereas other parameters like organic ligands, clay, and hydroxides also play a significant role. The worldwide occurrence of Se is in very broad range from 0.005 to 3.5 mg/kg. The concentration of Se in plants depends on the surrounding soil’s Se levels (Sakizadeh et al. 2016). A greater amount of selenate is taken up by plants than selenite and it is metabolized in chloroplasts by pathways similar to sulfur.

      The concentration of Se in sea water varies between 0.1 to 0.35 μg/l (Gaillardet et al. 2003). Natural waters have a concentration less than 1 μg/l (Conde and Sanz Alaejos 1997). Global Se average concentration in river waters is given in the range of 0.02–0.5 μg/l while in groundwater and surface water it ranges from 0.06 to 400 μg/l (World Health Organization 2011). The concentration of Se in water is dependent upon pH. The compounds which are soluble in water are converted at high and low pH and this results in an increase in concentration.

      Se can be transported to the air by natural processes such as volcanic eruptions, soil erosion, forest fires, and evaporation from ocean and sea. Mosses and peats in marine regions with increased Se levels when volatilized release Se into the air in the form of hydrogen selenide and elemental Se, selenites, and selenates in particulate form. Hydrogen selenide and Se dioxide are unstable in the air and are converted by oxidation into Se and H2O and into selenicious acid in moist conditions (Belcher et al. 1980). The ambient air Se concentration is generally very low and varies from 0.1 to 10 ng/m3 (Lee and Duffield 1979; Gilbert and Fornes 1980).

      The presence of Se in grains and vegetables is mainly accountable for the Se contents of soil in which they grow. The natural concentration of Se is very low, i.e. approximately 6 mg/g in vegetables like carrot, tomatoes, potatoes, cucumber, etc., even if they are grown in seleniferous soils. Some vegetables effectively accumulate Se from seleniferous soil, for instance onions and asparagus accumulate up to 17 μg/g. Fruits accumulate very low Se which is less than 10 μg/kg (Whanger 2004).

      3.2.2 Anthropogenic Sources of Contamination in Environment

      Some industrial waste and processes may contribute for the addition of high levels of Se in the environment. The major source of Se contamination in air is the combustion of fossil fuels (Shah et al. 2007). The elemental Se burns to form Se dioxide in the air. The main atmospheric Se emission includes oil refining factories, mining, and milling end product manufacturing. In 1978 Harr has reported that the fossil fuel burning, emissions from industries, and municipal wastes release almost 1500, 2700, and 360 tons of Se annually, respectively (Fishbein 1983). In Canada nonferrous smelters emitted 3.02 tons of Se in 1993 as reported by Skeaff and Dubreuil. Different kind of paper also contains Se (Skeaff and Dubreuil 1997).

      Many electronics industrial waste also contains Se as Se is an essential component in the electronics accessories such as capacitors, printers/toners, and photocopiers etc. It is also used in semiconductors, photoelectric cells, glass, and pharmaceuticals production, the waste of which goes into the landfills and incineration and is added to environment. Leachates obtained from landfilling units of such industries wastes show increased levels of Se.

      The radioactive isotope of Se, i.e. 79Se34 may also be a component of nuclear waste. The release of this isotope contributes Se content in soil, plants, and water when accidentally released from nuclear waste repositories or power plants. Smelting of ores such as nickel, zinc, and copper also releases Se in atmosphere through volatization. The Se concentration in the environment is increasing day by day and may lead to environmental pollution which is very harmful for human beings (Duce 1987).

      Se is a vital necessity to human, aquatic, and terrestrial organisms. The presence of Se in the diet has nutritional benefits to the organisms on the Earth while its deficiency or excess consumption can lead to an adverse effect in humas as well as in aquatic and terrestrial life.

      3.4.1 Human Population

Country Limit (μg/l)
Drinking water
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