Sulfur and Paraminosalicylic acid: Difference between pages

{{dablink|This article is about the chemical element. For other meanings of "sulfur" or "sulphur", see [[sulphur (disambiguation)]]}}

{{Infobox sulfur}}

'''Sulfur''' or '''sulphur''' ({{pronEng|ˈsʌlfɚ}}, [[#Spelling and etymology|see spelling below]]) is the [[chemical element]] that has the [[atomic number]] 16. It is denoted with the symbol '''S'''. It is an abundant [[Valence (chemistry)|multivalent]] [[non-metal]]. Sulfur, in its native form, is a yellow [[crystal]]line solid. In [[nature]], it can be found as the pure element and as [[sulfide]] and [[sulfate]] minerals. It is an essential element for life and is found in two [[amino acid]]s, [[cysteine]] and [[methionine]]. Its commercial uses are primarily in [[fertilizer]]s, but it is also widely used in [[gunpowder]], [[match]]es, [[insecticide]]s and [[fungicide]]s. Elemental sulfur crystals are commonly sought after by mineral collectors for their brightly colored [[polyhedron]] shapes. In nonscientific context it can also be referred to as '''[[brimstone]]'''.

== History ==

{{Expand-section|date=January 2008}}

[[Image:SulphurCrystal.jpg|thumb|left|Rough sulfur crystal]]

[[Image:Large Sulfur Crystal.jpg|thumb|left|Sulfur crystal from Agrigento, [[Sicily]].]]

Sulfur ([[Sanskrit]], ''sulvari''; [[Latin]] ''sulfur'' or ''sulpur'') was known in ancient times, and is referred to in the [[Bible|Biblical]] [[Pentateuch]] ([[Genesis]]).

English translations of the [[Bible]] commonly referred to sulfur as "[[brimstone]]", giving rise to the name of '[[fire and brimstone]]' [[sermon]]s, in which listeners are reminded of the fate of eternal damnation that awaits the unbelieving and unrepentant. It is from this part of the Bible that [[Hell]] is implied to "smell of sulfur", although sulfur, in itself, is in fact odorless. The "smell of sulfur" usually refers to either the odor of [[hydrogen sulfide]], e.g. from rotten egg, or of burning sulfur, which produces [[sulfur dioxide]], the smell associated with burnt matches. The smell emanating from raw sulfur originates from a slow oxidation in the presence of air. Hydrogen sulfide is the principal odor of untreated [[sewage]] and is one of several smelly sulfur-containing components of [[flatulance]] (along with sulfur-containing [[Thiol|mercaptans]]).

Sulfur was known in [[China]] since the 6th century BC, in a natural form that the Chinese had called 'brimstone', or ''shiliuhuang'' that was found in [[Hanzhong]].<ref name="yunming 487">{{cite journal | author = Zhang Yunming | year = 1986 | title = The History of Science Society: Ancient Chinese Sulfur Manufacturing Processes | journal = [[Isis (journal)|Isis]] | volume = 77 | doi = 10.1086/354207 | pages = 487}}</ref> By the 3rd century, the Chinese discovered that sulfur could be extracted from [[pyrite]].<ref name="yunming 487"/> Chinese Daoists were interested in sulfur's flammability and its reactivity with certain metals, yet its earliest practical uses were found in [[traditional Chinese medicine]].<ref name="yunming 487"/> A [[Song Dynasty]] military treatise of 1044 AD described different formulas for Chinese [[gun powder]], which is a mixture of [[potassium nitrate]] ({{chem|K||N||O|3}}), [[carbon]], and sulfur. Early [[alchemy|alchemists]] gave sulfur its own [[alchemical symbol]] which was a triangle at the top of a cross.

In 1777 [[Antoine Lavoisier]] helped convince the scientific community that sulfur was an element and not a compound. In 1867, sulfur was discovered in underground deposits in [[Louisiana]] and [[Texas]]. The overlying layer of earth was [[quicksand]], prohibiting ordinary mining operations, therefore the [[Frasch process]] was used.

=== Spelling and etymology ===

The element has traditionally been spelled ''sulphur'' in the [[United Kingdom]], most of [[the Commonwealth]] including [[India]], [[Malaysia]], [[South Africa]] and [[Hong Kong]], along with the rest of the [[Caribbean]] and the [[Republic of Ireland|Ireland]], but ''sulfur'' in the [[United States]], while both spellings are used in [[Australia]], [[New Zealand]] and [[Canada]]. [[IUPAC]] adopted the spelling “sulfur” in 1990, as did the [[Royal Society of Chemistry]] Nomenclature Committee in 1992<ref>[http://www.rsc.org/delivery/_ArticleLinking/DisplayArticleForFree.cfm?doi=JM99101FP055&JournalCode=JM Spelling of Sulfur (PDF)]</ref> and the [[Qualifications and Curriculum Authority]] for England and Wales recommended its use in 2000.<ref>[http://www.worldwidewords.org/topicalwords/tw-sul1.htm Worldwidewords], [[9 December]] [[2000]]</ref>

In Latin, the word is variously written ''sulpur'', ''sulphur'', and ''sulfur'' (the Oxford Latin Dictionary lists the spellings in this order). It is an original Latin name and not a [[Classical Greek]] loan, so the ''ph'' variant does not denote the Greek letter φ. Sulfur in Greek is ''thion'' (θείον), whence comes the prefix [[thio-]]. The simplification of the Latin word's p or ph to an f appears to have taken place towards the end of the classical period, with the f spelling becoming dominant in the medieval period.<ref>[http://elements.vanderkrogt.net/elem/s.html Vanderkrogt.net]</ref>

== Characteristics ==

[[Image:Burning-sulfur.png|thumb|right|Sulfur melts to a blood-red liquid. When burned, it emits a blue flame.]]

At room temperature, sulfur is a soft, bright-yellow solid. Elemental sulfur has only a faint odor, similar to that of [[matches]].

The odor associated with rotten eggs is due to [[hydrogen sulfide]] ({{chem|H|2|S}}) and organic sulfur compounds rather than elemental sulfur.

Sulfur burns with a blue flame that emits [[sulfur dioxide]], notable for its peculiar suffocating odor due to dissolving in the mucosa to form dilute [[sulfurous acid]]. Sulfur itself is insoluble in water, but [[solubility|soluble]] in [[carbon disulfide]] &mdash; and to a lesser extent in other non-polar organic solvents such as [[benzene]] and [[toluene]]. Common [[oxidation state]]s of sulfur include &minus;2, +2, +4 and +6. Sulfur forms stable compounds with all elements except the [[noble gas]]es.

Sulfur in the solid state ordinarily exists as cyclic crown-shaped S₈ molecules.

The [[crystallography]] of sulfur is complex. Depending on the specific conditions, the sulfur [[allotrope]]s form several distinct [[crystal structure]]s, with [[rhombic]] and [[monoclinic]] S₈ best known.

A noteworthy property of sulfur is that its [[viscosity]] in its molten state, unlike most other liquids, increases above temperatures of 200 °C due to the formation of [[polymer]]s. The molten sulfur assumes a dark red color above this temperature. At higher temperatures, however, the viscosity is decreased as depolymerization occurs.

[[Amorphous]] or "plastic" sulfur can be produced through the rapid cooling of molten sulfur. [[X-ray crystallography]] studies show that the amorphous form may have a [[helix|helical]] structure with eight atoms per turn. This form is [[Metastability in molecules|metastable]] at room temperature and gradually reverts back to crystalline form. This process happens within a matter of hours to days but can be rapidly catalyzed.

===Allotropes===

[[Image:Cyclooctasulfur-above-3D-balls.png|thumb|left|The structure of the cyclooctasulfur molecule, S₈.]]

{{Main|Allotropes of sulfur}}

Sulfur forms more than 30 solid [[allotropy|allotrope]]s, more than any other element.<ref>{{cite journal

| author = Ralf Steudel, Bodo Eckert

| title = Solid Sulfur Allotropes Sulfur Allotropes

| journal = Topics in Current Chemistry

| year = 2003

| volume = 230

| pages = 1–80

| doi = 10.1007/b12110}}</ref> Besides S₈, several other rings are known.<ref>{{cite journal

| author = Steudel, R.

| title = Homocyclic Sulfur Molecules

| journal = Topics Curr. Chem.

| year = 1982

| volume = 102

| pages = 149}}</ref> Removing one atom from the crown gives S₇, which is more deeply yellow than S₈. [[HPLC]] analysis of "elemental sulfur" reveals an equilibrium mixture of mainly S₈, but also S₇ and small amounts of S₆.<ref>{{cite journal

| author = Tebbe, F. N.; Wasserman, E.; Peet, W. G.; Vatvars, A. and Hayman, A. C.

| title = Composition of Elemental Sulfur in Solution: Equilibrium of {{chem|S|6}}, S₇, and S₈ at Ambient Temperatures

| journal = J. Am. Chem. Soc.

| year = 1982

| volume = 104

| pages = 4971

| doi = 10.1021/ja00382a050}}</ref> Larger rings have been prepared, including S₁₂ and S₁₈.<ref>{{cite journal

| author = Beat Meyer

| title = Solid Allotropes of Sulfur

| journal = Chem. Rev.

| year = 1964

| volume = 64

| issue = 4

| pages = 429–451

| doi = 10.1021/cr60230a004}}</ref><ref>{{cite journal

| author = Beat Meyer

| title = Elemental sulfur

| journal = Chem. Rev.

| year = 1976

| volume = 76

| pages = 367–388

| doi = 10.1021/cr60301a003}}</ref> By contrast, sulfur's lighter neighbor [[oxygen]] only exists in two states of allotropic significance: O₂ and O₃. [[Selenium]], the heavier analogue of sulfur, can form rings but is more often found as a polymer chain.

=== Isotopes ===

{{main|Isotopes of sulfur}}

Sulfur has 18 [[isotope]]s, four of which are stable: ³²S (95.02%), ³³S (0.75%), ³⁴S (4.21%), and ³⁶S (0.02%). Other than ³⁵S, the [[radioactive isotopes]] of sulfur are all short lived. ³⁵S is formed from [[cosmic ray]] [[spallation]] of ⁴⁰[[argon]] in the [[Earth's atmosphere|atmosphere]]. It has a [[half-life]] of 87 days.

When sulfide [[mineral]]s are precipitated, isotopic equilibration among solids and liquid may cause small differences in the δS-34 values of co-genetic minerals. The differences between minerals can be used to estimate the temperature of equilibration. The δ[[carbon|C]]-13 and δS-34 of coexisting [[carbonate]]s and sulfides can be used to determine the [[pH]] and [[oxygen]] [[fugacity]] of the ore-bearing fluid during ore formation.

In most [[forest]] ecosystems, sulfate is derived mostly from the atmosphere; weathering of ore minerals and evaporites also contribute some sulfur. Sulfur with a distinctive isotopic composition has been used to identify pollution sources, and enriched sulfur has been added as a tracer in [[hydrology|hydrologic]] studies. Differences in the [[natural abundance]]s can also be used in systems where there is sufficient variation in the ³⁴S of ecosystem components. [[Rocky Mountain]] lakes thought to be dominated by atmospheric sources of sulfate have been found to have different δS-34 values from lakes believed to be dominated by watershed sources of sulfate.

=== Occurrence ===

[[Image:NZ sulfur NI.jpg|thumb|left|Sulfur crystalites at [[Waiotapu]] [[hot springs]], [[New Zealand]]]]

Elemental sulfur can be found near [[hot spring]]s and [[volcanic]] regions in many parts of the world, especially along the [[Pacific Ring of Fire]]. Such volcanic deposits are currently mined in [[Indonesia]], [[Chile]], and [[Japan]]. [[Sicily]] is also famous for its sulfur mines.

Significant deposits of elemental sulfur also exist in [[salt domes]] along the coast of the [[Gulf of Mexico]], and in [[evaporite]]s in eastern Europe and western Asia. The sulfur in these deposits is believed to come from the action of [[anaerobic bacteria]] on [[Mineral#Sulfate class|sulfate minerals]], especially [[gypsum]], although apparently native sulfur may be produced by geological processes alone, without the aid of living organisms (see below). However, fossil-based sulfur deposits from salt domes are the basis for commercial production in the [[United States]], [[Poland]], [[Russia]], [[Turkmenistan]], and [[Ukraine]].

[[Image:AlbertaSulfurAtVancouverBC.jpg|thumb|right|Sulfur recovered from hydrocarbons in [[Alberta]], stockpiled for shipment at [[Vancouver]], [[British Columbia|B.C.]]]]

Sulfur production through [[hydrodesulfurization]] of oil, gas, and the [[Athabasca Oil Sands]] has produced a surplus - huge stockpiles of sulfur now exist throughout Alberta, Canada.

Common naturally occurring sulfur compounds include the [[Mineral#Sulfide class|sulfide minerals]], such as [[pyrite]] (iron sulfide), [[cinnabar]] (mercury sulfide), [[galena]] (lead sulfide), [[sphalerite]] (zinc sulfide) and [[stibnite]] (antimony sulfide); and the sulfates, such as gypsum (calcium sulfate), [[alunite]] (potassium aluminium sulfate), and [[barite]] (barium sulfate). It occurs naturally in volcanic emissions, such as from [[hydrothermal vent]]s, and from bacterial action on decaying sulfur-containing organic matter.

The distinctive colors of [[Jupiter (planet)|Jupiter]]'s [[volcano|volcanic]] moon, [[Io (moon)|Io]], are from various forms of molten, solid and gaseous sulfur. There is also a dark area near the [[Moon|Lunar]] [[Impact crater|crater]] [[Aristarchus (crater)|Aristarchus]] that may be a sulfur deposit.

Sulfur is present in many types of [[meteorite]]s. Ordinary chondrites contain on average 2.1% sulfur, and carbonaceous chondrites may contain as much as 6.6%. Sulfur in meteorites is normally present entirely as [[troilite]] (FeS), but other sulfides are found in some meteorites, and carbonaceous chondrites contain free sulfur, sulfates, and possibly other sulfur compounds.<ref>B. Mason, ''Meteorites'', (New York: John Wiley & Sons, 1962), p. 160.</ref>

== Extraction and production ==

===Extraction from natural resources===

Sulfur is extracted by mainly two processes: the Sicilian process and the [[Frasch process]]. The Sicilian process, which was first used in [[Sicily]], was used in ancient times to get sulfur from rocks present in volcanic regions. In this process, the sulfur deposits are piled and stacked in brick kilns built on sloping hillsides, and with airspaces between them. Then powdered sulfur is put on top of the sulfur deposit and ignited. As the sulfur burns, the heat melts the sulfur deposits, causing the molten sulfur to flow down the sloping hillside. The molten sulfur can then be collected in wooden buckets.

The second process used to obtain sulfur is the Frasch process. In this method, three concentric pipes are used: the outermost pipe contains superheated water, which melts the sulfur, and the innermost pipe is filled with hot compressed air, which serves to create foam and pressure. The resulting sulfur foam is then expelled through the middle pipe.

The Frasch process produces sulfur with a 99.5% purity content, and which needs no further purification. The sulfur produced by the Sicilian process must be purified by distillation.

===Production from hydrogen sulfide===

====Chemically====

The [[Claus process]] is used to extract elemental sulfur from [[hydrogen sulfide]] produced in [[hydrodesulfurization]] of petroleum or from [[natural gas]].

====Biologically====

In the biological route, hydrogen sulfide (H₂S) from natural gas or refinery gas is absorbed with a slight alkaline solution in a wet scrubber. Or the sulfide is produced by biological sulfate reduction. In the subsequent process step, the dissolved sulfide is biologically converted to elemental sulfur. This solid sulfur is removed from the reactor. This process has been built on commercial scale. The main advantages of this process are:

# no use of expensive chemicals,

# the process is safe as the H₂S is directly absorbed in an alkaline solution,

# no production of a polluted waste stream,

# re-usable sulfur is produced, and

# the process occurs under ambient conditions.

The biosulfur product is different from other processes in which sulfur is produced because the sulfur is hydrophillic. Next to straightforward reuses as source for sulfuric acid production, it can also be applied as sulfur fertilizer.<ref>{{cite journal

| author = Zessen, E. van, et al.

| title = Application of THIOPAQTM biosulphur in agriculture

| journal = Proceedings of Sulphur 2004, Barcelona (Spain), 24 - 27 Oct.

| year = 2004

| volume = 57 - 68}}</ref>

== Chemistry ==

{{Expand-section|date=January 2008}}

===Inorganic compounds===

[[Image:Sulfur powder.jpg|right|thumb|Sulfur powder.]]

[[Hydrogen sulfide]] has the characteristic smell of rotten eggs. Dissolved in water, hydrogen sulfide is acidic and will react with metals to form a series of metal sulfides. Natural metal sulfides are common, especially those of iron. Iron sulfide is called [[pyrite]], the so-called ''fool's gold''. Pyrite can show semiconductor properties.<ref>{{cite web | author = Nyle Steiner | date = 22 February 1 | title = Iron Pyrites Negative Resistance Oscillator | url = http://home.earthlink.net/~lenyr/iposc.htm | accessdate = 2007-08-15}}</ref> [[Galena]], a naturally occurring lead sulfide, was the first [[semiconductor]] discovered, and found a use as a signal [[rectifier]] in the "cat's whiskers" of early [[crystal radio]]s.

Many of the unpleasant odors of organic matter are based on sulfur-containing compounds such as [[methanethiol|methyl]] and [[ethanethiol|ethyl mercaptan]], also used to scent natural gas so that leaks are easily detectable. The odor of [[garlic]] and "[[skunk]] stink" are also caused by sulfur-containing organic compounds. Not all organic sulfur compounds smell unpleasant; for example, [[grapefruit mercaptan]], a sulfur-containing [[terpene|monoterpenoid]] is responsible for the characteristic scent of grapefruit.

Polymeric sulfur nitride has metallic properties even though it does not contain any [[metal]] atoms. This compound also has unusual electrical and optical properties. This polymer can be made from [[tetrasulfur tetranitride]] S₄N₄.

Phosphorus sulfides are useful in synthesis. For example, P₄S₁₀ and its derivatives [[Lawesson's reagent]] and [[naphthalen-1,8-diyl 1,3,2,4-dithiadiphosphetane 2,4-disulfide]] are used to replace oxygen from some organic molecules with sulfur.

[[Image:Sulfate-3D-vdW.png|thumb|right|The '''sulfate''' anion, SO₄²⁻]]

* [[Sulfide]]s (S²⁻), a complex family of compounds usually derived from S²⁻. [[Cadmium sulfide]] (CdS) is an example.

* [[Sulfites]] (SO₃²⁻), the salts of [[sulfurous acid]] (H₂SO₃) which is generated by dissolving SO₂ in water. Sulfurous acid and the corresponding sulfites are fairly strong reducing agents. Other compounds derived from SO₂ include the pyrosulfite or metabisulfite ion (S₂O₅²⁻).

* [[Sulfate]]s (SO₄²⁻), the salts of [[sulfuric acid]]. Sulfuric acid also reacts with SO₃ in equimolar ratios to form [[pyrosulfuric acid]] (H₂S₂O₇).

* [[sodium thiosulfate|Thiosulfates]](S₂O₃²⁻).Sometimes referred as thiosulfites or "hyposulfites", Thiosulfates are used in photographic fixing (HYPO) as reducing agents. Ammonium thiosulfate is being investigated as a [[cyanide]] replacement in leaching [[gold]].[http://doccopper.tripod.com/gold/AltLixiv.html]

* [[Sodium dithionite]], {{chem|Na|2|S|2|O|4}}, is the highly reducing dianion derived from hyposulfurous/dithionous acid.

* [[Sodium dithionate]] (Na₂S₂O₆).

* [[Polythionic acid]]s (H₂S_''n''O₆), where ''n'' can range from 3 to 80.

* [[Peroxymonosulfuric acid]] (H₂SO₅) and [[peroxydisulfuric acid]]s (H₂S₂O₈), made from the action of SO₃ on concentrated [[hydrogen peroxide|H₂O₂]], and [[sulfuric acid|H₂SO₄]] on concentrated H₂O₂ respectively.

* [[Sodium polysulfide]]s (Na₂S_x)

* [[Sulfur hexafluoride]], SF₆, a dense gas at ambient conditions, is used as nonreactive and nontoxic propellant

* Sulfur nitrides are chain and cyclic compounds containing only S and N. [[Tetrasulfur tetranitride]] S₄N₄ is an example.

* [[Thiocyanate]]s contain the SCN⁻ group. Oxidation of thiocyanoate gives [[thiocyanogen]], (SCN)₂ with the connectivity NCS-SCN.

===Organic compounds===

(R, R', and R'' are organic groups such as CH₃):

[[Image:Dithiane33d.png|thumb|right|An organic sulfur compound, [[dithiane]].]]

* [[Thioether]]s have the form ''R''-S-''R&prime;''. These compounds are the sulfur equivalents of [[ether]]s.

* [[Sulfonium]] ions have the formula RR'S-'R'", i.e. where three groups are attached to the cationic sulfur center. [[Dimethylsulfoniopropionate]] (DMSP; (CH₃)₂S⁺CH₂CH₂COO⁻) is a sulfonium ion, which is important in the marine organic [[sulfur cycle]].

* [[Thiol]]s (also known as mercaptans) have the form R-SH. These are the sulfur equivalents of [[alcohol]]s.

* [[Thiolate]]s ions have the form R-S^-. Such anions arise upon treatment of [[thiol]]s with base.

* [[Sulfoxide]]s have the form ''R''-S(=O)-''R''&prime;. The simplest sulfoxide, [[dimethyl sulfoxide|DMSO]], is a common solvent.

* [[Sulfone]]s have the form ''R''-S(=O)₂-''R''&prime;. A common sulfone is sulfolane C₄H₈SO₂.

''See also [[:category:Sulfur compounds|Category: sulfur compounds]] and [[organosulfur chemistry]]''

==Applications==

{{Expand-section|date=January 2008}}

One of the direct uses of sulfur is in [[vulcanization]] of rubber, where [[polysulfide]]s crosslink organic polymers. Sulfur is a component of [[gunpowder]]. It reacts directly with methane to give [[carbon disulfide]], which is used to manufacture [[cellophane]] and [[rayon]].<ref name=Nehb>{{cite encyclopedia |last=Nehb |first=Wolfgang |authorlink= |coauthors=Vydra, Karel |editor= |encyclopedia=Ullmann's Encyclopedia of Industrial Chemistry |title=Sulfur |edition= |date= |year=2006 |month= |publisher=Wiley-VCH Verlag |volume= |location= |id= |isbn= |doi=10.1002/14356007.a25_507.pub2 |pages= |quote= }}</ref>

Elemental sulfur is mainly used as a precursor to other chemicals. Approximately 85% (1989) is converted to [[sulfuric acid]] ([[hydrogen|H]]₂S[[oxygen|O]]₄), which is of such prime importance to the [[world economy|world's economies]] that the production and consumption of sulfuric acid is an indicator of a nation's industrial development.<ref>http://www.pafko.com/history/h_s_acid.html Sulfuric Acid Growth</ref> For example, more sulfuric acid is produced in the [[United States]] every year than any other industrial chemical.{{Fact|date=August 2008}} The principal use for the acid is the extraction of phosphate ores for the production of fertilizer manufacturing. Other applications of sulfuric acid include oil refining, wastewater processing, and mineral extraction.<ref name=Nehb/>

Sulfur compounds are also used in [[detergents]], [[fungicide]]s, [[dyestuff]]s, and agrichemicals. In silver-based [[photography]] sodium and ammonium [[sodium thiosulfate|thiosulfate]] are used as "fixing agents."

Sulfur is an ingredient in some acne treatments.

An increasing application is as fertilizer. Standard sulfur is hydrophobic and therefore has to be covered with a surfactant by bacteria in the ground before it can be oxidized to sulfate. This makes it a slow release fertilizer, which cannot be taken up by the plants instantly, but has to be oxidized to sulfate over the growth season. Biologically produced sulfur particles are naturally hydrophilic due to a biopolymer coating. This sulfur is therefore easier to disperse over the land (via spraying as a diluted slurry), and results in a faster release.

[[Sulfite]]s, derived from burning sulfur, are heavily used to [[Bleach (chemical)|bleach]] [[paper]]. They are also used as preservatives in dried [[fruit]].

[[Magnesium sulfate]], better known as [[Epsom salts]], can be used as a [[laxative]], a bath additive, an [[exfoliant]], a [[magnesium]] supplement for plants, or a [[desiccant]].

===Specialized applications===

Sulfur is used as a light-generating medium in the rare lighting fixtures known as [[sulfur lamp]]s.

===Historical applications===

In the late 18th century, [[furniture]] makers used molten sulfur to produce decorative [[inlay]]s in their craft. Because of the [[sulfur dioxide]] produced during the process of melting sulfur, the craft of sulfur inlays was soon abandoned. Molten sulfur is sometimes still used for setting steel bolts into drilled concrete holes where high shock resistance is desired for floor-mounted equipment attachment points. Pure powdered sulfur was also used as a medicinal tonic and laxative. Sulfur was also used in baths for people who had fits.

===Fungicide===

<!-- Image with unknown copyright status removed: [[Image:Biosulfur as fungicide2.jpg|right|thumb|200px|Apple on which biosulfur has just been applied as a natural fungicide.]] -->Sulfur is the only fungicide used in [[organically farmed]] apple production against the main disease [[apple scab]] under colder conditions. Sulfur is also a major fungicide in conventional culture of grapes, strawberry, many vegetables and several other crops. It has a good efficacy against a wide range of powdery mildew diseases as well as black spot. Sulfur is one of the oldest pesticides used in agriculture. In organic production sulfur is the most important fungicide used. Biosulfur (biologically produced elemental sulfur with hydrophillic characteristics) can be used well for these applications.

===Insecticide===

Sulfur is also used as an [[organic farming|"organic"]] (i.e. "green") insecticide, effective against [[mites]].

<br clear="all">

== Biological role ==

{{main|Sulfur assimilation}}

See [[sulfur cycle]] for more on the inorganic and organic natural transformations of sulfur.

Sulfur is an essential component of all living [[cell (biology)|cells]].

Inorganic sulfur forms a part of [[iron-sulfur cluster]]s, and sulfur is the bridging ligand in the [[copper|Cu]]_A site of [[cytochrome c oxidase]], a basic substance involved in utilization of oxygen by all aerobic life.

Sulfur may also serve as chemical food source for some primitive organisms: some forms of [[bacterium|bacteria]] use [[hydrogen sulfide]] (H₂S) in the place of water as the [[electron]] donor in a primitive [[photosynthesis]]-like process in which oxygen is the electron receptor. The [[photosynthesis|photosynthetic]] green and purple sulfur [[bacteria]] and some [[chemolithotroph]]s use elemental oxygen to carry out such oxidization of hydrogen sulfide to produce elemental sulfur (S^o), oxidation state = 0. Primitive bacteria which live around deep ocean volcanic vents oxidize hydrogen sulfide in this way with oxygen: see [[giant tube worm]] for an example of large organisms (via bacteria) making metabolic use of hydrogen sulfide as food to be oxidized.

The so-called [[sulfur bacteria]], by contrast, "breathe sulfate" instead of oxygen. They use sulfur as the electron acceptor, and reduce various oxidized sulfur compounds back into sulfide-- often into hydrogen sulfide. They also can grow on a number of other partially oxidized sulfur compounds (e. g. thiosulfate, thionates, polysulfides, sulfite). These bacteria are responsible for the rotten egg smell of some intestinal gases and decomposition products.

Sulfur is a part of many bacterial defense molecules. For example, though sulfur is not a part of the [[lactam]] ring, it is a part of most [[beta lactam]] antibiotics, including the [[penicillin]]s, [[cephalosporins]], and [[monobactam]]s.

Sulfur is absorbed by [[plant]]s via the [[root]]s from soil as the [[sulfate]] [[ion]] and reduced to sulfide before it is incorporated into [[cysteine]] and other organic sulfur compounds (see [[sulfur assimilation]] for details of this process).

Sulfur is regarded as secondary nutrient although plant requirements for sulfur are equal to and sometimes exceed those for phosphorus. However sulfur is recognized as one of the major nutrients essential for plant growth, root nodule formation of legumes and plants protection mechanisms. Sulfur deficiency has become widespread in many countries in Europe. Because atmospheric inputs of sulfur will continue to decrease, the deficit in the sulfur input/output is likely to increase, unless sulfur fertilizers are used.

In [[plants]] and [[animals]] the [[amino acid]]s [[cysteine]] and [[methionine]] contain sulfur, as do all [[polypeptide]]s, [[protein]]s, and [[enzyme]]s which contain these amino acids. [[Homocysteine]] and [[taurine]] are other sulfur-containing acids which are similar in structure, but which are not coded for by [[DNA]], and are not part of the [[primary structure]] of proteins. [[Glutathione]] is an important sulfur-containing tripeptide which plays a role in cells as a source of chemical reduction potential in the cell, through its sulfhydryl (-SH) moiety. Many important cellular enzymes use prosthetic groups ending with -SH moieties to handle reactions involving acyl-containing biochemicals: two common examples from basic metabolism are [[coenzyme A]] and [[alpha-lipoic acid]].

[[Disulfide bond]]s (S-S bonds) formed between cysteine residues in peptide chains are very important in protein assembly and structure. These strong covalent bonds between peptide chains give proteins a great deal of extra toughness and resiliency. For example, the high strength of feathers and hair is in part due to their high content of S-S bonds and their high content of cysteine and sulfur (eggs are high in sulfur because large amounts of the element are necessary for feather formation). The high disulfide content of hair and feathers contributes to their indigestibility, and also their odor when burned.

===Traditional medical role for elemental sulfur===

In traditional medical skin treatment which predates modern era of scientific medicine, elemental sulfur has been used mainly as part of creams to alleviate various conditions such as psoriasis, eczema and acne. The mechanism of action is not known, although elemental sulfur does oxidize slowly to sulfurous acid, which in turn (though the action of [[sulfite]]) acts as a mild reducing and antibacterial agent.

== Precautions ==

{{Expand-section|date=January 2008}}

Carbon disulfide, carbon oxysulfide, hydrogen sulfide, and sulfur dioxide should all be handled with care.

Although [[sulfur dioxide]] is sufficiently safe to be used as a [[food additive]] in small amounts, at high concentrations it reacts with moisture to form [[sulfurous acid]] which in sufficient quantities may harm the [[lungs]], [[eyes]] or other [[Biological tissue|tissues]]. In organisms without lungs such as insects or plants, it otherwise prevents [[Respiration (physiology)|respiration]].

[[Hydrogen sulfide]] is [[toxic]]. Although very pungent at first, it quickly deadens the sense of smell, so potential victims may be unaware of its presence until death or other symptoms occur.

=== Environmental impact ===

The burning of [[coal]] and/or [[petroleum]] by industry and [[power plants]] generates [[sulfur dioxide]] (S[[oxygen|O]]₂), which reacts with atmospheric water and oxygen to produce [[sulfuric acid]] (H₂SO₄). This sulfuric acid is a component of [[acid rain]], which lowers the [[pH]] of [[soil]] and freshwater bodies, sometimes resulting in substantial damage to the [[environment (biophysical)|environment]] and [[chemical weathering]] of statues and structures. Fuel standards increasingly require sulfur to be extracted from [[fossil fuel]]s to prevent the formation of acid rain. This extracted sulfur is then refined and represents a large portion of sulfur production. In coal fired power plants, the flue gases are sometimes purified. In more modern power plants that use [[synthesis gas|syngas]] the sulfur is extracted before the gas is burned.

== See also ==

*[[Sulfur cycle]]

*[[Disulfide bond]]

*[[Sulfonium]] S⁺, S⁺R₃

*[[Ultra-low sulfur diesel]]

*[[Claus process]]

*[[Shell-Paques sulfide removal/sulfur recovery process]]

==References==

{{reflist}}

Leslie KS, Millington GWM, Levell NJ. (2004) Sulphur and skin: from Satan to Saddam! J Cosm Dermatol 3: 94-98.

== External links ==

{{Commons|Sulfur}}

{{wiktionary|sulfur}}

* [http://library.tedankara.k12.tr/chemistry/vol2/allotropy/z129.htm Sulfur phase diagram]

* [http://www.webelements.com/webelements/elements/text/S/index.html WebElements.com &ndash; Sulfur]

* [http://www.chemicalelements.com/elements/s.html chemicalelements.com/sulfur]

* [http://www.stromboli.net/perm/vulcano/sulphur-vulcano-en.html Crystalline, liquid and polymerization of sulphur on Vulcano Island, Italy]

* [http://extoxnet.orst.edu/pips/sulfur.htm Sulfur and its use as a pesticide]

{{clear}}

{{Compact periodic table}}

[[Category:Chalcogens]]

[[Category:Chemical elements]]

[[Category:Dietary minerals]]

[[Category:Inorganic polymers]]

[[Category:Nonmetals]]

[[Category:Pyrotechnic fuels]]

[[Category:Agricultural chemicals]]

[[Category:Sulfur|*]]

{{Link FA|fa}}

[[af:Swawel]]

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[[be:Сера]]

[[bs:Sumpor]]

[[bg:Сяра]]

[[ca:Sofre]]

[[cs:Síra]]

[[co:Zolfu]]

[[cy:Sylffwr]]

[[da:Svovl]]

[[de:Schwefel]]

[[et:Väävel]]

[[el:Θείο]]

[[es:Azufre]]

[[eo:Sulfuro]]

[[eu:Sufre]]

[[fa:گوگرد]]

[[fr:Soufre]]

[[fur:Solfar]]

[[ga:Sulfar]]

[[gv:Sulfur]]

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[[hi:गन्धक]]

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[[id:Belerang]]

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[[he:גופרית]]

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[[kn:ಗಂಧಕ]]

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[[ht:Souf]]

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[[hu:Kén]]

[[mk:Сулфур]]

[[ml:ഗന്ധകം]]

[[mi:Pungatara]]

[[mr:सल्फर]]

[[mn:Хүхэр]]

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[[myv:Палыкандал]]

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[[ru:Сера]]

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[[simple:Sulfur]]

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[[sl:Žveplo]]

[[sr:Сумпор]]

[[sh:Sumpor]]

[[su:Walirang]]

[[fi:Rikki]]

[[sv:Svavel]]

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