Disulfur monoxide or sulfur suboxide is an inorganic compound with the formula S<sub>2</sub>O, one of the lower sulfur oxides. It is a colourless gas and condenses to give a roughly dark red coloured solid that is unstable at room temperature.
occurs rarely in natural atmospheres, but can be made by a variety of laboratory procedures. For this reason, its spectroscopic signature is very well understood.
Like sulfur dioxide (and, indeed, most molecules) but unlike sulfur monoxide, disulfur, or dioxygen, the ground state of disulfur monoxide is a singlet.
Condensed solid S<sub>2</sub>O absorbs at (roughly indigo) and (roughly lime). These bands have been assigned to decomposition products S<sub>3</sub> and S<sub>4</sub>.
In the ultraviolet, S<sub>2</sub>O has absorption band systems in the ranges 250âÂÂ340 nm and 190âÂÂ240 nm. There are bands at 323.5 and 327.8 nm. The band in the 315âÂÂ340 nm range is due to the transition.
Gaseous disulfur monoxide does not absorb light in the visible spectrum.
The microwave spectrum of S<sub>2</sub>O has the following rotational parameters: A = 41915.44 MHz, B = 5059.07 MHz, and C = 4507.19 MHz. Moreover, the microwave spectrum suggests the S−S−O angle is 117.88ð with S−S and S−O bond lengths of 188.4 and 146.5 pm, respectively. In the 327.8 nm excited state, the central angle tightens to 109ð.
The harmonic frequency for S−S stretching is 415.2 cm<sup>âÂÂ1</sup>.
Disulfur monoxide was discovered by Peter W. Schenk in 1933 with a glow discharge though sulfur vapour and sulfur dioxide. He discovered that the gas could survive for hours at single digit pressures of mercury in clean glass, but it decomposed near . Schenk assigned the formula as SO and called it sulfur monoxide. In 1956, D. J. Meschi and R. J. Myers established the formula as S<sub>2</sub>O.
Oxidizing sulfur with copper(II) oxide:
A relatively pure generator is the reaction of thionyl chloride with silver(I) sulfide:
Also 5,6-di-tert-butyl-2,3,7-trithiabicyclo[2.2.1]hept-5-ene 2-endo-7-endo-dioxide decomposes upon heating with release of S<sub>2</sub>O:
Triphenylphosphine sulfide reacts with sulfinyltosylimide to give S<sub>2</sub>O and tosyltriphenylphosphinylamide:
Volcanoes on Io produce substantial quantities of . It can form between 1% and 6% when hot 100-bar S<sub>2</sub> and SO<sub>2</sub> gas erupts from volcanoes. It is believed that Pele on Io is surrounded by solid S<sub>2</sub>O.
Disulfur monoxide is too unstable to survive at standard conditions, but transient sources include incomplete combustion of sulfur vapor and thermal decomposition of sulfur dioxide in a glow discharge.
Disulfur monoxide occurs as a ligand bound to transition metals, typically with hapticity 2. Examples include ; ; and . These complexes are closely related to transition metal sulfur dioxide complexes.
On decomposition at room temperature it forms SO<sub>2</sub> via the formation of polysulfur oxides:
reacts with diazoalkanes to form dithiirane 1-oxides.