The lower sulfur oxides are a group of inorganic compounds with the formula SmOn, where 2m > n. These species are often unstable and thus rarely encountered in everyday life. They are significant intermediates in the combustion of elemental sulfur.[1] Some well characterized examples include sulfur monoxide (SO), its dimer S2O2, and a series of cyclic sulfur oxides, SnOx (x = 1, 2), based on cyclic Sn rings.

Structure of S2O
Space-filling model of S2O

Interest in the lower sulfur oxides has increased because of the need to understand terrestrial atmospheric sulfur pollution and the finding that the extraterrestrial atmospheres of Io, one of Jupiter's moons, and Venus contain significant amounts of sulfur oxides. Some compounds reported by early workers such as the blue "sesquioxide", S2O3, formed by dissolving sulfur in liquid SO3 appears to be a mixture of polysulfate salts of the S2+4 and S2+8 ions.[1]

Sulfur monoxide, disulfur dioxide, disulfur monoxide

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These species are well characterized in the gas phase, but they cannot be isolated as solids or liquids. Instead, when condensed, they undergo dimerization and oligomerization, usually yielding sulfur dioxide and elemental sulfur. At a few millibars pressure, the relative stabilities are S2O > S2O2 > SO.[2] Sulfur monoxide (SO) and its dimer (S2O2) have been trapped at low temperature. Disulfur dioxide (S2O2) is a dimer of sulfur monoxide. It has C2v structure (planar).

Disulfur monoxide (S2O) is an analogue of sulfur dioxide. Like SO2 as well as ozone (O3), and trisulfur (S3), it adopts a bent structure. The S-S bond length is 188.4 pm, the S-O bond is 146.5 pm and the SSO angle is 117.88°. The two dipole moment components are μa = 0.875 D and μb = 1.18 D.[3] This species decomposes to give a polymeric sulfur oxides ("PSO's") with the approximate formula [S3O]n. PSO's decompose at room temperature to elemental sulfur and SO2. PSO's have been proposed to be responsible for the colour of Io.[4]

Trisulfur monoxide, S3O is an unstable molecule. It has been detected in the gas phase using neutralization-reionization mass spectrometry. Both cyclic and chain structures were found.[5]

Cyclic SnOx (x = 1, 2)

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Ball-and-stick model of cyclooctasulfur monoxide, S8O

A number of monoxides SnO are known where n = 5-10. The oxygen atom is exocyclic.[2] They can be prepared by oxidising the homocycles with trifluoroperoxyacetic acid:[1]

Sn + CF3C(O)OOH → SnO + CF3C(O)OH

The compounds are yellow or orange-coloured and thermally unstable near room temperature.[1]

formula color (25 °C) m.p. (°C)[2]
S6O yellow 39
S7O orange 55
S7O2 intense orange 60–62 (decomp.)
S8O orange 78 (decomposition)
S9O intensely yellow 32-34
S10O orange 51 (decomp.)

One dioxide is well characterized: the deep orange S7O2 (m.p. 60–62 °C with decomposition), which arises using trifluoroperoxoacetic acid.[1]

References

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  1. ^ a b c d e Greenwood, Norman N.; Earnshaw, Alan (1997). Chemistry of the Elements (2nd ed.). Butterworth-Heinemann. ISBN 978-0-08-037941-8.
  2. ^ a b c R. Steudel (2003). "Sulfur-Rich Oxides SnO and SnO2". In Steudel, R. (ed.). Elemental Sulfur und Sulfur-Rich Compounds II. Berlin-Heidelberg: Springer. doi:10.1007/b13185. ISBN 9783540449515.
  3. ^ Meschi, D.J.; Myers R.J. (1959). "The microwave spectrum, structure, and dipole moment of disulfur monoxide". Journal of Molecular Spectroscopy. 3 (1–6): 405–416. Bibcode:1959JMoSp...3..405M. doi:10.1016/0022-2852(59)90036-0.
  4. ^ Baklouti D., D; Schmitt, B.; Brissaud, O. (November 2004). "Infrared study of lower sulfur oxides on Io's surface". Bulletin of the American Astronomical Society. 36: 1099. Bibcode:2004DPS....36.1607B.
  5. ^ de Petris, G; Rosi M Troiani A (2006). "S3O and S3O+ in the gas phase: ring and open-chain structures". Chemical Communications (42): 4416–4418. doi:10.1039/b609646h. PMID 17057862.