16
S
Sulfur
Atomic Mass 32.066
Electron Configuration [Ne]3s23p4
Oxidation States +6, +4, -2
Year Discovered Ancient

Identifiers

Element Name Sulfur
Element Symbol S
InChI InChI=1S/S
InChIKey NINIDFKCEFEMDL-UHFFFAOYSA-N

Properties

Atomic Weight

[32.059, 32.076]

32.066

32.06

[32.059,32.076]

Electron Configuration

[Ne]3s23p4

Atomic Radius

Van der Waals Atomic Radius : 180 pm (Van der Waals)

Empirical Atomic Radius : 100pm (Empirical)

Covalent Atomic Radius : 105(3) pm (Covalent)

Oxidation States

+6, +4, -2

6, 5, 4, 3, 2, 1, -1, -2 ​(a strongly acidic oxide)

Ground Level

3P2

Ionization Energy

10.360 eV

10.3600167 ± 0.0000014 eV

Electronegativity

Pauling Scale Electronegativity : 2.58(Pauling Scale)

Allen Scale Electronegativity : 2.589(Allen Scale)

Electron Affinity

2.077eV

2.04eV

Atomic Spectra

Lines Holdings

Levels Holdings

Physical Description

Solid

Element Classification

Non-metal

Element Period Number

3

Element Group Number

16 - Chalcogen

Density

2.067 grams per cubic centimeter

Melting Point

388.36 K (115.21°C or 239.38°F)

115.21°C

Boiling Point

717.75 K (444.60°C or 832.28°F)

444.60°C

Estimated Crustal Abundance

3.50×102 milligrams per kilogram

Estimated Oceanic Abundance

9.05×102 milligrams per liter

History

The name derives from the Latin sulphurium and the Sanskrit sulveri. Sulfur was known as brenne stone for "combustible stone" from which brim-stone is derived. It was known from prehistoric times and thought to contain hydrogen and oxygen. In 1809, the French chemists Louis-Joseph Gay-Lussac and Louis-Jacques Thenard proved the elemental nature of sulfur.

Sulfur, the tenth most abundant element in the universe, has been known since ancient times. Sometime around 1777, Antoine Lavoisier convinced the rest of the scientific community that sulfur was an element. Sulfur is a component of many common minerals, such as galena (PbS), gypsum (CaSO4·2(H2O), pyrite (FeS2), sphalerite (ZnS or FeS), cinnabar (HgS), stibnite (Sb2S3), epsomite (MgSO4·7(H2O)), celestite (SrSO4) and barite (BaSO4). Nearly 25% of the sulfur produced today is recovered from petroleum refining operations and as a byproduct of extracting other materials from sulfur containing ores. The majority of the sulfur produced today is obtained from underground deposits, usually found in conjunction with salt deposits, with a process known as the Frasch process. Sulfur is a pale yellow, odorless and brittle material. It displays three allotropic forms: orthorhombic, monoclinic and amorphous. The orthorhombic form is the most stable form of sulfur. Monoclinic sulfur exists between the temperatures of 96°C and 119°C and reverts back to the orthorhombic form when cooled. Amorphous sulfur is formed when molten sulfur is quickly cooled. Amorphous sulfur is soft and elastic and eventually reverts back to the orthorhombic form.

Known to the ancients; referred to in Genesis as brimstone.

Historical Atomic Weights

Year Atomic Weight (uncertainty) [u] Reference
2009 [32.059, 32.076] https://doi.org/10.1351/PAC-REP-10-09-14
1999 32.065(5) https://doi.org/10.1351/pac200173040667
1983 32.066(6) https://doi.org/10.1351/pac198456060653
1969 32.06(1) https://doi.org/10.1351/pac197021010091
1961 32.064(3) https://doi.org/10.1021/ja00881a001
1951 32.066(3) https://doi.org/10.1039/JR9530000001
1947 32.066 https://doi.org/10.1039/JR9510000001
1931 32.06 https://doi.org/10.1039/JR9310001617
1925 32.064 https://doi.org/10.1039/CT9252700913
1916 32.06 https://doi.org/10.1021/ja02176a001
1909 32.07 https://doi.org/10.1021/ja01931a001
1902 32.06 https://doi.org/10.1007/BF01370337

Historical Isotopic Abundances

Year Isotope Abundance (uncertainty) Reference
2013 32S [0.9441, 0.9529] https://doi.org/10.1515/pac-2015-0503
2013 33S [0.007 29, 0.007 97] https://doi.org/10.1515/pac-2015-0503
2013 34S [0.0396, 0.0477] https://doi.org/10.1515/pac-2015-0503
2013 36S [0.000 129, 0.000 187] https://doi.org/10.1515/pac-2015-0503
2001 32S 0.9499(26) https://doi.org/10.1063/1.1836764
2001 33S 0.0075(2) https://doi.org/10.1063/1.1836764
2001 34S 0.0425(24) https://doi.org/10.1063/1.1836764
2001 36S 0.0001(1) https://doi.org/10.1063/1.1836764
1997 32S 0.9493(31) https://doi.org/10.1351/pac199870010217
1997 33S 0.0076(2) https://doi.org/10.1351/pac199870010217
1997 34S 0.0429(28) https://doi.org/10.1351/pac199870010217
1997 36S 0.0002(1) https://doi.org/10.1351/pac199870010217
1989 32S 0.9502(9) https://doi.org/10.1351/pac199163070991
1989 33S 0.0075(4) https://doi.org/10.1351/pac199163070991
1989 34S 0.0421(8) https://doi.org/10.1351/pac199163070991
1989 36S 0.0002(1) https://doi.org/10.1351/pac199163070991
1983 32S 0.9502(9) https://doi.org/10.1351/pac198456060675
1983 33S 0.0075(1) https://doi.org/10.1351/pac198456060675
1983 34S 0.0421(8) https://doi.org/10.1351/pac198456060675
1983 36S 0.0002(1) https://doi.org/10.1351/pac198456060675
1979 32S 0.9502(6) https://doi.org/10.1351/pac198052102349
1979 33S 0.0075(1) https://doi.org/10.1351/pac198052102349
1979 34S 0.0421(8) https://doi.org/10.1351/pac198052102349
1979 36S 0.0002(1) https://doi.org/10.1351/pac198052102349
1975 32S 0.95 https://doi.org/10.1351/pac197647010075
1975 33S 0.0076 https://doi.org/10.1351/pac197647010075
1975 34S 0.0422 https://doi.org/10.1351/pac197647010075
1975 36S 0.0002 https://doi.org/10.1351/pac197647010075

Description

Sulfur is pale yellow, odorless, brittle solid, which is insoluble in water but soluble in carbon disulfide. In every state, whether gas, liquid or solid, elemental sulfur occurs in more than one allotropic form or modification; these present a confusing multitude of forms whose relations are not yet fully understood.

In 1975, University of Pennsylvania scientists reported synthesis of polymeric sulfur nitride, which has the properties of a metal, although it contains no metal atoms. The material has unusual optical and electrical properties.

High-purity sulfur is commercially available in purities of 99.999+%.

Amorphous or "plastic" sulfur is obtained by fast cooling of the crystalline form. X-ray studies indicate that amorphous sulfur may have a helical structure with eight atoms per spiral. Crystalline sulfur seems to be made of rings, each containing eight sulfur atoms, which fit together to give a normal X-ray pattern.

Users

Most of the sulfur that is produced is used in the manufacture of sulfuric acid (H2SO4). Large amounts of sulfuric acid, nearly 40 million tons, are used each year to make fertilizers, lead-acid batteries, and in many industrial processes. Smaller amounts of sulfur are used to vulcanize natural rubbers, as an insecticide (the Greek poet Homer mentioned "pest-averting sulphur" nearly 2,800 years ago!), in the manufacture of gunpowder and as a dying agent.

In addition to sulfuric acid, sulfur forms other interesting compounds. Hydrogen sulfide (H2S) is a gas that smells like rotten eggs. Sulfur dioxide (SO2), formed by burning sulfur in air, is used as a bleaching agent, solvent, disinfectant and as a refrigerant. When combined with water (H2O), sulfur dioxide forms sulfurous acid (H2SO3), a weak acid that is a major component of acid rain.

Sulfur is a component of black gunpowder, and is used in the vulcanization of natural rubber and a fungicide. It is also used extensively in making phosphatic fertilizers. A tremendous tonnage is used to produce sulfuric acid, the most important manufactured chemical.

It is used to make sulfite paper and other papers, to fumigate, and to bleach dried fruits. The element is a good insulator.

Sulfur is essential to life. It is a minor constituent of fats, body fluids, and skeletal minerals.

Sources

Sulfur is found in meteorites. R.W. Wood suggests that the dark area near the crater Aristarchus is a sulfur deposit.

Sulfur occurs native in the vicinity of volcanos and hot springs. It is widely distributed in nature as iron pyrites, galena, sphalerite, cinnabar, stibnite, gypsum, epsom salts, celestite, barite, etc.

Compounds

Organic compounds containing sulfur are very important. Calcium sulfur, ammonium sulfate, carbon disulfide, sulfur dioxide, and hydrogen sulfide are but a few of the many important compounds of sulfur.

See more information at the Sulfur compound page.

Element Forms

CID Name Formula SMILES Molecular Weight
5362487 sulfur S [S] 32.07
29109 sulfide S-2 [S-2] 32.07
5460611 sulfur(1-) S- [S-] 32.07
156022697 sulfur-34(2-) S-2 [34S-2] 33.9678670
71309543 sulfur-34 S [34S] 33.9678670
71309715 sulfur-33 S [33S] 32.97145891
71311181 sulfur-32 S [32S] 31.97207117
644342 sulfur-35(2-) S-2 [35S-2] 34.9690323

Handling And Storage

Carbon disulfide, hydrogen sulfide, and sulfur dioxide should be handled carefully. Hydrogen sulfide in small concentrations can be metabolized, but in higher concentrations it quickly can cause death by respiratory paralysis.

It quickly deadens the sense of smell. Sulfur dioxide is a dangerous component in atmospheric air pollution.

Isotopes

Stable Isotope Count 4
Summary Eleven isotopes of sulfur exist. None of the four isotopes that are found in nature are radioactive. A finely divided form of sulfur, known as flowers of sulfur, is obtained by sublimation.

Isotopes in Biology

The stable sulfur isotope-amount ratio n(34S)/n(32S) has been used to distinguish whether animal tissues grew in freshwater or in marine ecosystems. The isotopes do not fractionate (separate) substantially with trophic influences (the movement of sulfur through and into plant and animal systems), and the isotope-amount ratio n(34S)/n(32S) is usually substantially different between freshwater and marine environments. As an example, by analyzing sulfur isotope-amount ratios in bird feathers, the environment in which the bird was living when these feathers developed can be determined. This enables one to track bird habitats and migration patterns throughout the year (Fig. IUPAC.16.1) [141].

Fig. IUPAC.16.1: Variation in atomic weight with isotopic composition of selected sulfur-bearing materials (modified from [13], [17]).

[13] M. W. Wieser, T. B. Coplen. Pure Appl Chem.83, 359 (2011).
[17] T. B. Coplen, J. A. Hopple, J. K. Böhlke, H. S. Peiser, S. E. Rieder, H. R. Krouse, K. J. R. Rosman, T. Ding, R. D. Vocke, K. Revesz, A. Lamberty, P. D. P. Taylor, P. D. Bièvre. United States Geological Survey Water-Resources Investigations Report, 01-4222, (2002).
[141] C. E. Hebert, M. Bur, D. Sherman, J. L. Shutt. Ecol. Appl.18, 561 (2008).

Isotopes in Earth/Planetary Science

Molecules, atoms, and ions of the stable isotopes of sulfur possess slightly different physical and chemical properties, and they commonly will be fractionated during physical, chemical, and biological processes, giving rise to variations in isotopic abundances and in atomic weights. There are substantial variations in the isotopic abundances of sulfur in natural terrestrial materials (Fig. IUPAC.16.2). These variations are useful in investigating the origin of substances and studying environmental, hydrological, and geological processes [13], [17]. The isotope-amount ratio n(34S)/n(32S) can be used to trace natural and anthropogenic sources of sulfur. Examples include studies of acid mine drainage, the cycling of sulfur in agricultural watersheds, groundwater contamination from landfills, and sources of salinity in coastal aquifers [142], [143], [144].

Fig. IUPAC.16.2: Sulfur isotopic abundances of Tianyuan 1 early modern human found in Eurasia, three terrestrial animals from Tianyuan Cave (Tianyuandong) in the Zhoukoudian region of China, and two fish from Donghulin (modified from [146]). Based on sulfur, carbon, and nitrogen isotopic analyses of bones from the early modern human and the associated animals in Tianyuan Cave and the Donghulin site, Hu et al. [146] conclude that the human most likely obtained a substantial portion of its protein from a freshwater ecosystem, probably from freshwater fish.

[13] M. W. Wieser, T. B. Coplen. Pure Appl Chem.83, 359 (2011).
[17] T. B. Coplen, J. A. Hopple, J. K. Böhlke, H. S. Peiser, S. E. Rieder, H. R. Krouse, K. J. R. Rosman, T. Ding, R. D. Vocke, K. Revesz, A. Lamberty, P. D. P. Taylor, P. D. Bièvre. United States Geological Survey Water-Resources Investigations Report, 01-4222, (2002).
[142] International Atomic Energy Agency. Guidelines for the use of Isotopes of Sulfur in Soil–Plant Studies, International Atomic Energy Agency Vienna, Austria (2003).
[143] I. M. Cozzarelli, J. M. Suflita, G. A. Ulrich, S. H. Harris, M. A. Scholl, J. L. Schlottmann, S. Christenson. Environ. Sci. Technol.34, 4025 (2000).
[144] M. Edraki, S. D. Golding, K. A. Baublys, M. G. Lawrence. Appl. Geochem.20, 789 (2005).
[146] Y. Hu, H. Shang, H. Tong, O. Nehlich, W. Liu, C. Zhao, J. Yu, C. Wang, E. Trinkausd, M. P. Richards. Proc. Natl. Acad. Sci.106, 10971 (2009).

Isotopes in Forensic Science and Anthropology

The isotope-amount ratio n(34S)/n(32S) can be used to authenticate the dietary source of cattle. First, stable isotopes are measured to infer the dietary source of the cattle. Once the source of the diet is found, the isotopic compositions can be traced in certain muscle groups of the cattle and can be used to determine if the diet of the animal has been changed or if the feed is consistent with what the animal has been claimed to have been fed [145].

[145] B. Bahar, A. P. Moloney, F. J. Monahan, S. M. Harrison, A. Zazzo, C. M. Scrimgeour, I. S. Begley, O. Schmidt. J. Anim. Sci.87, 905 (2009).

Isotopes in Geochronology

35S has a half-life of 87 days, which is an ideal duration for use as a conservative tracer in atmospheric processes. 35SO2 gas is produced as a natural product of argon exposure to cosmic rays in the atmosphere. Because 35SO2 gas is present in the atmosphere and then precipitates and falls as moisture in the form of 35SO4 2-, 35S can act as a tracer to study air mass transport dynamics and atmospheric oxidation capacity [147]. Analyses of 35S in lake water and precipitation can also be used as a tracer to monitor contributions of sulfur that originated in precipitation to surface waters. If a water tests positive for the isotope 35S, it provides evidence that the water had been affected by recent (<~1 year) precipitation [148], [149], [150]. 35S is used in direct labeling of elemental sulfur or sulfate sources to trace the fate of sulfur in fertilizers [142].

[142] International Atomic Energy Agency. Guidelines for the use of Isotopes of Sulfur in Soil–Plant Studies, International Atomic Energy Agency Vienna, Austria (2003).
[147] A. Priyadarshi, G. Dominguez, J. Savarino, M. Thiemens. Geophys. Res. Lett.38, L13808 (2011).
[148] INSTAAR University of Colorado Boulder. Sulfur 35, INSTAAR University of Colorado Boulder (2014), Feb. 24; http://snobear.colorado.edu/Daniel/isotopes/sulfur35.html.
[149] Y. Kim, K. S. Lee, D. C. Koh, D. H. Lee, S. G. Lee, W. B. Park, G. W. Koh, N. C. Woo. J. Hydrol.270, 282 (2003).
[150] Y. L. Hong, G. Kim. Anal. Chem.77, 3390 (2005).

Isotope Mass and Abundance

Isotope Atomic Mass (uncertainty) [u] Abundance (uncertainty)
32S 31.972 071 174(9) [0.9441, 0.9529]
33S 32.971 458 91(1) [0.007 29, 0.007 97]
34S 33.967 8670(3) [0.0396, 0.0477]
36S 35.967 081(2) [0.000 129, 0.000 187]
Isotope Atomic Mass (uncertainty) [u] Abundance (uncertainty)
32S 31.9720711744(14) 0.9499(26)
33S 32.9714589098(15) 0.0075(2)
34S 33.967867004(47) 0.0425(24)
36S 35.96708071(20) 0.0001(1)

Atomic Mass, Half Life, and Decay

Nuclide Atomic Mass and Uncertainty [u] Half Life and Uncertainty Discovery Year Decay Modes, Intensities and Uncertainties [%]
26S 26.029716 ± 0.000644 [Estimated] Not-specified <79ns 2p ?
27S 27.018777 ± 0.00043 [Estimated] 16.3 ms ± 0.2 1986 β+=100%; β+p=61±0.3%; β+2p=3.0±0.6%
28S 28.004372762 ± 0.000171767 125 ms ± 10 1982 β+=100%; β+p=20.7±1.9%
29S 28.996678000 ± 0.000014 188 ms ± 4 1964 β+=100%; β+p=46.4±1%
30S 29.984906770 ± 0.000000221 1.1798 s ± 0.0003 1961 β+=100%
31S 30.979557002 ± 0.000000246 2.5534 s ± 0.0018 1940 β+=100%
32S 31.97207117354 ± 0.00000000141 Stable 1920 IS=94.85±25.5%
33S 32.97145890862 ± 0.00000000144 Stable 1926 IS=0.763±2%
34S 33.967867011 ± 0.000000047 Stable 1926 IS=4.365±23.5%
35S 34.969032321 ± 0.000000043 87.37 d ± 0.04 1936 β-=100%
36S 35.967080692 ± 0.000000201 Stable 1938 IS=0.0158±1.7%
37S 36.971125500 ± 0.000000212 5.05 m ± 0.02 1945 β-=100%
38S 37.971163300 ± 0.000007699 170.3 m ± 0.7 1958 β-=100%
39S 38.975133850 ± 0.000053677 11.5 s ± 0.5 1971 β-=100%
40S 39.975482561 ± 0.000004274 8.8 s ± 2.2 1971 β-=100%
41S 40.979593451 ± 0.0000044 1.99 s ± 0.05 1979 β-=100%; β-n ?
42S 41.981065100 ± 0.000003 1.016 s ± 0.015 1979 β-=100%; β-n<1%
43S 42.986907635 ± 0.000005335 265 ms ± 13 1979 β-=100%; β-n=40±1%
43Sm 42.986907635 ± 0.000005335 415.0 ns ± 2.6 2000 IT=100%
44S 43.990118846 ± 0.0000056 100 ms ± 1 1979 β-=100%; β-n=18±0.3%
44Sm 43.990118846 ± 0.0000056 2.619 us ± 0.026 2005 IT=100%
45S 44.996414 ± 0.000322 [Estimated] 68 ms ± 2 1989 β-=100%; β-n≈54%; β-2n ?
46S 46.000687 ± 0.000429 [Estimated] 50 ms ± 8 1989 β-=100%; β-n ?; β-2n ?
47S 47.007730 ± 0.000429 [Estimated] 24 ms >200ns [Estimated] 1989 β- ?; β-n ?; β-2n ?
48S 48.013301 ± 0.000537 [Estimated] 10 ms >200ns [Estimated] 1990 β- ?; β-n ?; β-2n ?
49S 49.021891 ± 0.000626 [Estimated] 4 ms >400ns [Estimated] 2018 β- ?; β-n ?; β-2n ?

Information Sources

  1. 1.  PubChem
  2. 2.  Atomic Mass Data Center (AMDC), International Atomic Energy Agency (IAEA)
  3. 3.  IUPAC Commission on Isotopic Abundances and Atomic Weights (CIAAW)
  4. 4.  Jefferson Lab, U.S. Department of Energy
    LICENSE
    Please see citation and linking information https https://www.jlab.org/privacy-and-security-notice
  5. 5.  Los Alamos National Laboratory, U.S. Department of Energy
  6. 6.  NIST Physical Measurement Laboratory
  7. 7.  IUPAC Periodic Table of the Elements and Isotopes (IPTEI)
    LICENSE
    Copyright (c) 2020 International Union of Pure and Applied Chemistry. The International Union of Pure and Applied Chemistry (IUPAC) contribution within Pubchem is provided under a CC-BY-NC-ND 4.0 license, unless otherwise stated.
    https://creativecommons.org/licenses/by-nc-nd/4.0/
  8. 8.  PubChem Elements
    Sulfur

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