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Sulphur, selenium, tellurium, haloids (fluorine, chlorine, bromine, iodine)

Sulphur, selenium, tellurium, haloids (fluorine, chlorine, bromine, iodine). Sulfur (S) Universe: 500 ppm (by weight)  Sun: 400 ppm (by weight)  Carbonaceous meteorite: 41000 ppm  Earth's Crust: 420 ppm  Seawater: 928 ppm. Sulfur in magmatic processes.

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Sulphur, selenium, tellurium, haloids (fluorine, chlorine, bromine, iodine)

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  1. Sulphur, selenium, tellurium, haloids (fluorine, chlorine, bromine, iodine)

  2. Sulfur (S) Universe: 500 ppm (by weight)  Sun: 400 ppm (by weight)  Carbonaceous meteorite: 41000 ppm  Earth's Crust: 420 ppm  Seawater: 928 ppm

  3. Sulfur in magmatic processes Native sulfur reacts with water under hydrothermal conditionsto form a complex mixture of dissolved sulfur oxyanions,hydrogen sulfide, and polysulfides. Native sulfur is formed ascondensates in and around fumaroles, as a precipitate in craterlakes, as a microbial alteration product of gypsum or anhydritein sediments (most notably associated with saltdomes) and asa weathering product of metal sulfides. It forms decomposition of sulfur-bearing organic matter in waste dumps of coal mines. However the most sulfur are in sulfide and sulfate compounds.

  4. Sulfur in magmatic processes The sulfidesconcentratedfirstlyintheearlymagmaticdifferenciates. Largemasses of chalcopyrite, pyrrhotite, pentlandite etc. occurintheseprocesses. Inmagmaticrockssulfur is an uncommonelement. Thereare a fewsilicates, whichcontainsitinform of sulfate anion, e.g. Noseán - Na8Al6Si6O24(SO4)•H2O, Haüyn - (Na,Ca)4-8 Al6Si6(O,S)24(SO4,Cl)1-2. The most sulfides, sulfosaltsappearinpost-magmaticprocesses(we had anyinformationaboutitatthemetalsorsemimetals).

  5. Sulfur in weathering and sedimentary processes The global sulfur cycle is a complex network of processes thattransfer sulfur between four main reservoirs: the ocean, theocean floor basalts, evaporite deposits and reduced marinesediments (the latter are the largest reservoir of sulfur). By comparison, the atmosphere, rivers, lakes, aquifers,soils and biomass are far smaller sulfur reservoirs whichact essentially as links in the transfer of sulfur from the continents to the ocean. As sulfur cycles through these various reservoirs,it changes in oxidation state from predominantly S(VI)in aerobic environments to S(-II) or S(-I) in anaerobic environments.Rivers, and to a small extent groundwater, transport sulfurin the form of sulfate from the continents to the ocean.

  6. Sulfur in weathering and sedimentary processes Weathering of metal sulfides, the dissolution of gypsum and anhydrite, and sea-saltsulfate account for most of the natural riverine flux.In the oceans, sulfate is primarily removed via sulfate reductionand evaporite deposition. Thereduction of sulfate in marine sediments leads to the formationof pyrite and organic compounds containing sulfur. This process is mediated bysulfate-reducing bacteria that oxidize organic matter. Sulfate is also extracted from seawater by seawater-basaltinteraction at mid-oceanic ridges. As seawater interacts with basalt, most of thesulfate is precipitated as anhydrite upon heating of the seawater.

  7. Sulfur in weathering and sedimentary processes One of the main sulfur compounds, the formation of sulfate requires relativelyoxidizing conditions, and sulfate minerals are thereforeparticularly common in oxygenated surface environments.They are also common precipitates from oxidizing hydrothermalsystems, and anhydrite (CaSO4 ) may crystallize as a primarymineral phase from oxidized, sulfur-rich magmas. Some of sulfate minerals may be found in hydrothermal depositseither as primary precipitates (e.g. barite, celestine),or as oxidation products of sulfideminerals during secondary (supergene) alteration (e.g. anglesite, brochantite).

  8. Sulfur in weathering and sedimentary processes The hydrated sulfate gypsum (CaSO4 • 2H2O) shares manyof the occurrences of anhydrite, and is an important evaporite mineral. Gypsum is also common in the supergene alteration zoneof sulfide mineral deposits, along with other hydrated sulfates such as chalcanthite (CuSO4 • 5H2O), melanterite (FeSO4 • 7H2O), and epsomite (MgSO4 • 7H2O). Hydroxylated sulfates are a diverse group of minerals,and include the important end-members alunite(KAl3 [SO4 ]2[OH]6), jarosite (KFe3[SO4] 2[OH]6), antlerite(Cu3[SO4][O]4), and brochantite (Cu4 [SO4][OH]6). All ofthese minerals are characteristic of near-surface oxygenatedconditions, and are common supergene alteration products of sulfides.

  9. Selenium (Se) Universe: 0.03 ppm (by weight)  Carbonaceous meteorite: 130 ppm  Earth's Crust: 0.05 ppm  Seawater: Atlantic surface: 4.6 x 10-8 ppm     Atlantic deep: 1.8 x 10-7 ppm

  10. Selenium in magmatic processes Minerals of selenium include selenides (Se2-), native selenium (Se), selenites (MxSeO3, Se4+) and selenates (MxSeO4, Se6+). The relative stability of these phases depends on Eh and pH conditions.In reducing environments, selenium isomorphicallysubstitutes for sulfur in sulfides, the selenides are rare. In selenium-rich environments, however,complete solid solution between sulfide and selenide end-members (e.g. galena(PbS) and clausthalite(PbSe) solid solution. In most igneous rock types,selenium is a trace component in accessory sulfides. Trace to minor concentrations of seleniumare found in native sulfur associated with volcanic exhalations and oxidized sulfide deposits.

  11. Selenium in weathering and sedimentary processes Rare selenites and selenates are in association with oxidized sulfide ores and vent formations associated with burning coalseams. The formation of selenites and selenates is limited bya number of factors: selenite ions are strongly adsorbed tomineral surfaces and selenates require a combination of highlyoxidizing, alkaline, and arid conditions. Selenite and selenate are stable over a broad range of conditions that covermost natural surface waters, where selenate dominates in alkaline, oxidized waters. Selenium is an essential nutrient at trace concentrations butis toxic at elevated levels.

  12. Tellurium (Te) Universe: 0.009 ppm (by weight)  Carbonaceous meteorite: 2.1 ppm  Earth's Crust: 0.001 ppm  Seawater:   Atlantic surface: 1.6 x 10-7 ppm     Atlantic deep: 7 x 10-8 ppm

  13. Tellurium in magmatic processes Tellurium is a chalcophile element. It occurs in sulfide mineralsof silver, copper, lead, mercury and nickel, replacing sulfur,especially in chalcopyrite, bornite and pentlandite. As a nativeelement it is rarely found in hydrothermal veins. It usuallyforms independent minerals in sulfide-bearing gold veins (morethan 40 minerals are known) mostly tellurides with silver,gold, copper, lead, and bismuth: calaverite AuTe2 , nagyágite Au2Sb2Pb10Te6S12 , petzite Ag3AuTe2 , sylvanite (Au,Ag)Te4 , hessite Ag2Te, etc. All tellurides formed at thelow-temperature phase of the hydrothermal process. It has notbeen detected yet in rock-forming minerals because of its low content.

  14. Tellurium in weathering and sedimentary processes In weathering conditions tellurium may be oxidized to tellurites or tellurates (similar to selenites and selenates), or oxides, which are slightly mobile and usually sorbed by Fehydroxides. There has been no systematic investigation of telluriumin soils over the world, although it has low mobility in various soil conditions. It is often accumulated in coal as a result of sorption by organic matter.

  15. Fluorine (F) Universe: 0.4 ppm (by weight)  Sun: 0.5 ppm (by weight)  Carbonaceous meteorite: 89 ppm  Earth's Crust: 950 ppm  Seawater:    Atlantic surface: 1 x 10-4 ppm     Atlantic deep: 9.6 x 10-5 ppm

  16. Fluorine in magmatic processes Fluorine is a common element in igneous and metamorphic rocks. The atomic radius of fluoride is similar to the hydroxylion (OH-) and substitutes for it in minerals such as apatites, micas, pyroxenes, amphiboles, tourmalines. In general ultramafic rocks have smallerfluorine contents than those with higher percentages of SiO2 . The most important F-bearing mineral, fluorite (CaF2) concentrates in the post-magmatic stadiums (from pegmatitic till epithermal). There are characteristic mineral in alkaline magmatites: villiaumite (NaF), a RFF-fluorides (yttrofluorite) and cryolite (Na3AlF6).

  17. Fluorine in weathering and sedimentary processes Phosphate and fluorite contain the most concentrated occurrencesof fluorine in sedimentary rocks. Phosphate depositsconsist of phosphorite, a combination of apatites which contain calcium fluorapatite. Fluorite (CaF2 ) occurs as primary veins and fillings in some limestone and dolomite deposits. The fluorine in sediments have often volcanic origin.

  18. Chlorine (Cl) Universe: 1 ppm (by weight)  Sun: 8 ppm (by weight)  Carbonaceous meteorite: 380 ppm  Earth's Crust: 130 ppm  Seawater: 18000 ppm

  19. Chlorine in magmatic processes Chlorine may occur as a trace element substitutingfor hydroxyl ions in some hydrous minerals such as micas and amphiboles, sodalite, scapolite. It can be important component in apatites (chlorapatite), similar that fluorine. The F: Cl ratio increases from basic to acidic magmatic rocks. Sal ammoniac (cubic NH4Cl) forms in volcanic exhalations.

  20. Chlorine in weathering and sedimentary processes Evaporitic salts are the most important chlorine-containing rocks, which include mainly halite (NaCl), sylvite (KCl) and carnotite (KMgCl3 • 6H2O). There are some chlorides in the oxidation zone of ore deposits, mainly in arid clime: chlorargyrite (AgCl), cotunnite (PbCl2), nantokite (CuCl), calomel (HgCl).

  21. Chlorine in weathering and sedimentary processes Chlorine entered the oceans over time by weathering and erosion from the rocks. Among other, the chlorine reached near modern concentrations in the oceans by the early Precambrian via volcanic emissions. Volcanism, sedimentation and erosion facilitate chlorine exchange between ocean and continental reservoirs. Tending to remain with the aqueous phase of the cooling magma untilthe last crystallizing fraction, chlorine may be deposited assalts in hydrothermal fractures and veins in the surrounding country rock.

  22. Bromine (Br) Universe: 0.007 ppm (by weight)  Carbonaceous meteorite: 1.2 ppm  Earth's Crust: 3 ppm  Seawater: 67.3 ppm

  23. Bromine in magmatic and sedimentary processes Bromine is generally associated with volatile components andis most highly concentrated in the upper mantle and crust. The very low concentration in rocks suggests that only a small fractionof bromine is fixed in igneous minerals; most of the bromineis extruded with residual fluids and in the magmatic gases. Close in ionic radius to chlorine, bromidecan substitute in structure containing chloride, where mostbromine occurs. The most common bromine mineral is bromargyrite (AgBr), which may be found in association with chlorargyrite(AgCI). Halite (NaCI) and other sedimentary rocks maycontain up to 0.2% bromine.

  24. Iodine (I) Universe: 0.0001 ppm (by weight)  Carbonaceous meteorite: 0.26 ppm  Earth's Crust: 1.4 ppm  Seawater:   Atlantic surface: 4.89 x 10-2 ppm     Atlantic deep: 5.6 x 10-2 ppm

  25. Iodine in magmatic and sedimentary processes Iodine content appears to be uniformand less than 1 mg/kg in common rock-forming minerals.Sedimentary rocks generally contain more iodine than igneousrocks, and over a broader range of concentrations. Two typesof deposit are particularly rich in iodine: phosphate rock(0.8-130 mg/kg) and the caliche (nitrate) deposits with ~400 mg/kg iodine (sometimes in form of iodate compounds). The weathering of rock releases up to about half of the original iodine contentas water-soluble compounds, mainly iodide. Soils contain much more iodine than the rocks from which they are derived. Recent marine sediments are particularly rich in iodine(5-200 mg/kg); they are the largest repository of iodine at the Earth's surface.

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