Oxocarbon

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Template:Short description

In chemistry, an oxocarbon or oxide of carbon is a chemical compound consisting only of carbon and oxygen.[1][2] The simplest and most common oxocarbons are carbon monoxide (CO) and carbon dioxide (Template:Chem2). Many other stable (practically if not thermodynamically) or metastable oxides of carbon are known, but they are rarely encountered, such as carbon suboxide (Template:Chem2 or Template:Chem2) and mellitic anhydride (Template:Chem2).

  File:Chemfm carbon monoxide 3 1.svg   File:Chemfm carbon dioxide.svg   File:Chemfm carbon suboxide.svg   File:Chemfm mellitic anhydride.svg
CO
Carbon
monoxide 		Template:Chem2
Carbon
dioxide 		Template:Chem2
Carbon
suboxide 		Template:Chem2
Mellitic
anhydride

Many other oxides are known today, most of them synthesized since the 1960s. Some of these new oxides are stable at room temperature. Some are metastable or stable only at very low temperatures, but decompose to simpler oxocarbons when warmed. Many are inherently unstable and can be observed only momentarily as intermediates in chemical reactions or are so reactive that they exist only in gas phase or have only been detected by matrix isolation.

Graphene oxide and other stable polymeric carbon oxides with unbounded molecular structures exist.[3][4]

Overview

Carbon dioxide (CO2) occurs widely in nature, and was incidentally produced by humans since pre-historical times, by breathing, the combustion of carbon-containing substances and fermentation of foods such as beer and bread. It was gradually recognized as a chemical substance, formerly called spiritus sylvestris ("forest spirit") or "fixed air", by various chemists in the 17th and 18th centuries.

Carbon monoxide may occur in combustion, too, and was used (though not recognized) since antiquity for the smelting of iron from its ores. Like the dioxide, it was described and studied in the West by various alchemists and chemists since the Middle Ages. Its true composition was discovered by William Cruikshank in 1800.

Carbon suboxide was discovered by Benjamin Brodie in 1873, by passing electric current through carbon dioxide.[5]

The fourth "classical" oxide, mellitic anhydride (C12O9), was apparently obtained by Liebig and Wöhler in 1830 in their study of mellite ("honeystone"), but was characterized only in 1913, by Meyer and Steiner.[6][7][8]

Brodie also discovered in 1859 a fifth compound called graphite oxide, consisting of carbon and oxygen in ratios varying between 2:1 and 3:1; but the nature and molecular structure of this substance remained unknown until a few years ago, when it was renamed graphene oxide and became a topic of research in nanotechnology.[3]

Notable examples of unstable or metastable oxides that were detected only in extreme situations are dicarbon monoxide radical (:C=C=O), carbon trioxide (CO3),[9] carbon tetroxide (Template:Chem/link),[10][11] carbon pentoxide (Template:Chem/link),[12] carbon hexoxide (Template:Chem/link)[13] and 1,2-dioxetanedione (C2O4).[14][15] Some of these reactive carbon oxides were detected within molecular clouds in the interstellar medium by rotational spectroscopy.[16]

Many hypothetical oxocarbons have been studied by theoretical methods but have yet to be detected. Examples include oxalic anhydride (C2O3 or O=(C2O)=O), ethylene dione (C2O2 or O=C=C=O)[17] and other linear or cyclic polymers of carbon monoxide (-CO-)n (polyketones),[18] and linear or cyclic polymers of carbon dioxide (-CO2-)n, such as the dimer 1,3-dioxetanedione (C2O4).[19]

  File:Chemfm oxalic anhydride.svg   File:Chemfm ethylene dione.svg   File:Chemfm 1 3 dioxetanedione.svg
  C2O3
Oxalic
anhydride 		  C2O2
Ethylene
dione 		  C2O4
1,3-Dioxetane-
dione

General structure

Normally, carbon is tetravalent, while oxygen is divalent, and in most oxocarbons (as in most other carbon compounds) each carbon atom may be bound to four other atoms, while oxygen may be bound to at most two. Moreover, while carbon can connect to other carbons to form arbitrarily large chains or networks, chains of three or more oxygens are rarely if ever observed. Thus the known electrically neutral oxocarbons generally consist of one or more carbon skeletons (including cyclic and aromatic structures) connected and terminated by oxide (-O-, =O) or peroxide (-O-O-) groups.

Carbon atoms with unsatisfied bonds are found in some oxides, such as the diradical C2O or :C=C=O; but these compounds are generally too reactive to be isolated in bulk.[20] Loss or gain of electrons can result in monovalent negative oxygen (-Template:Chem/link), trivalent positive oxygen (≡Template:Chem/link), or trivalent negative carbon (≡Template:Chem/link). The last two are found in carbon monoxide, C≡O+.[21] Negative oxygen occurs in most oxocarbon anions.

Linear carbon dioxides

One family of carbon oxides has the general formula CnO2, or O=(C=)nO — namely, a linear chain of carbon atoms, capped by oxygen atoms at both ends. The first members are

Some higher members of this family have been detected in trace amounts in low-pressure gas phase and/or cryogenic matrix experiments, specifically for n = 7[24]Template:Rp and n = 17, 19, and 21.[25]Template:Rp

Linear carbon monoxides

Another family of oxocarbons are the linear carbon monoxides CnO. The first member, ordinary carbon monoxide CO, seems to be the only one that is practically stable in the pure state at room temperature (though it is not thermodynamically stable at standard temperature and pressure, see Boudouard reaction). Photolysis of the linear carbon dioxides in a cryogenic matrix leads to loss of CO, resulting in detectable amounts of even-numbered monoxides such as C2O, C4O,[20] and C6O.[24] The members up to n=9 have also been obtained by electrical discharge on gaseous C3O2 diluted in argon.[26] The first three members have been detected in interstellar space.[26]

When n is even, the molecules are believed to be in the triplet (cumulene-like) state, with the atoms connected by double bonds and an unfilled orbital in the first carbon — as in :C=C=O, :C=C=C=C=O, and, in general, :(C=)n=O. When n is odd, the triplet structure is believed to resonate with a singlet (acetylene-type) polar state with a negative charge on the carbon end and a positive one on the oxygen end, as in C≡C−C≡O+, C≡C−C≡C−C≡O+, and, in general, (C≡C−)(n−1)/2C≡O+.[26] Carbon monoxide itself follows this pattern: its predominant form is believed to be C≡O+.[21]

Radialene-type cyclic polyketones

Another family of oxocarbons that has attracted special attention are the cyclic radialene-type oxocarbons CnOn or (CO)n.[27] They can be regarded as cyclic polymers of carbon monoxide, or n-fold ketones of n-carbon cycloalkanes. Carbon monoxide itself (CO) can be regarded as the first member. Theoretical studies indicate that ethylene dione (C2O2 or O=C=C=O) and cyclopropanetrione C3O3 do not exist.[17][18] The next three members — C4O4, C5O5, and C6O6 — are theoretically possible, but are expected to be quite unstable,[18] and so far they have been synthesized only in trace amounts.[28][29]

  File:Chemfm ethylene dione.svg   File:Chemfm cyclopropanetrione.svg   File:Chemfm cyclobutanetetrone.svg   File:Chemfm cyclopentanepentone.svg   File:Chemfm cyclohexanehexone.svg
(CO)2
Ethylene
dione 		(CO)3
Cyclopropane-
trione 		(CO)4
Cyclobutane-
tetrone 		(CO)5
Cyclopentane-
pentone 		(CO)6
Cyclohexane-
hexone

On the other hand, the anions of these oxocarbons are quite stable, and some of them have been known since the 19th century.[27] They are

The cyclic oxide C6O6 also forms the stable anions of tetrahydroxy-1,4-benzoquinone (C6O64−) and benzenehexol (C6O66−),[37] The aromaticity of these anions has been studied using theoretical methods.[38][39]

New oxides

Many new stable or metastable oxides have been synthesized since the 1960s, such as:

  File:Chemfm benzoquinonetetracarboxylic dianhydride.svg   File:Chemfm ethylenetetracarboxylic dianhydride.svg   File:Chemfm tetrahydroxy 1 4 benzoquinone bisoxalate.svg
C10O8
Benzoquinone-
tetracarboxylic
dianhydride 		C6O6
Ethylene-
tetracarboxylic
dianhydride 		C10O10
Tetrahydroxy-
1,4-benzoquinone
bisoxalate
  File:Chemfm tetrahydroxy 1 4 benzoquinone biscarbonate.svg   File:Chemfm dioxane tetraketone.svg   File:Chemfm hexaphenol trisoxalate.svg
C8O8
Tetrahydroxy-
1,4-benzoquinone
biscarbonate 		C4O6
Dioxane
tetraketone 		C12O12
Hexahydroxybenzene
trisoxalate
  File:Chemfm hexaphenol triscarbonate.svg   File:Chemfm tris 3 4 dialkynyl 3 cyclobutene 1 2 dione.svg   File:Chemfm tetrakis 3 4 dialkynyl 3 cyclobutene 1 2 dione.svg
C9O9
Hexahydroxybenzene
triscarbonate 		C24O6
Tris(3,4-dialkynyl-
3-cyclobutene-
1,2-dione) 		C32O8
Tetrakis(3,4-dialkynyl-
3-cyclobutene-
1,2-dione)
  File:Chemfm hexaoxotricyclobutabenzene.svg
C12O6
Hexaoxotricyclo-
butabenzene

Many relatives of these oxides have been investigated theoretically, and some are expected to be stable, such as other carbonate and oxalate esters of tetrahydroxy-1,2-benzoquinone and of the rhodizonic, croconic, squaric, and deltic acids.[18]

Polymeric carbon oxides

Carbon suboxide spontaneously polymerizes at room temperature into a carbon-oxygen polymer, with 3:2 carbon:oxygen atomic ratio. The polymer is believed to be a linear chain of fused six-membered lactone rings, with a continuous carbon backbone of alternating single and double bonds. Physical measurements indicate that the mean number of units per molecule is about 5–6, depending on the formation temperature.[4][49]

  File:Chemfm poly carbon suboxide Ls.svg File:Chemfm poly carbon suboxide 1sHs.svg File:Chemfm poly carbon suboxide i 1sHs.svg File:Chemfm poly carbon suboxide sR.svg
Terminating and repeating units of polymeric C3O2.[4]
  File:Chemfm poly carbon suboxide Lb 1bHb bR.svg File:Chemfm poly carbon suboxide Lb 2bHb bR.svg File:Chemfm poly carbon suboxide Lb 3bHb bR.svg File:Chemfm poly carbon suboxide Lb 4bHb bR.svg
Oligomers of C3O2 with 3 to 6 units.[4]

Carbon monoxide compressed to 5 GPa in a diamond anvil cell yields a somewhat similar reddish polymer with a slightly higher oxygen content, which is metastable at room conditions. It is believed that CO disproportionates in the cell to a mixture of CO2 and C3O2; the latter forms a polymer similar to the one described above (but with a more irregular structure), that traps some of the CO2 in its matrix.[50][51]

Another carbon-oxygen polymer, with C:O ratio 5:1 or higher, is the classical graphite oxide[3] and its single-sheet version graphene oxide.

Fullerene oxides and ozonides

More than 20 oxides and ozonides of fullerene are known:[52]

  • C60O (2 isomers)
  • C60O2 (6 isomers)
  • C60O3 (3 isomers)
  • C120O
  • C120O4 (4 isomers)
  • C70O
  • C140O

and others.

See also

References

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  1. IUPAC, Compendium of Chemical Terminology, 5th ed. (the "Gold Book") (2025). Online version: (1995) "Oxocarbons". Script error: No such module "CS1 identifiers".Script error: No such module "TemplatePar".
  2. West, R. (ed.) (1980), Oxocarbons. Academic Press, New York.
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  6. Liebig, J. and Wöhler, F. (1830), Ueber die Zusammensetzung der Honigsteinsäure Poggendorfs Annalen der Physik und Chemie, vol. 94, Issue 2, pp.161–164. Online version accessed on 2009-07-08.
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  8. Bugge (1914), Chemie: En neues Kohenoxyd. Review of Meyer and Steiner's discovery of C12O9. Naturwissenschaftliche Wochenschrift, volume 13/29, issue 12, 22 March 1914, p. 188. Online version accessed on 2009-07-09.
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  16. H. M. Pickett E. A. Cohen B. J. Drouin J. C. Pearson (2003), Submillimeter, Millimeter, and Microwave Spectral Line Catalog. NASA/JPL, Online version accessed on 2009-07-11.
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  20. a b Maier, Günter and Reisenauer, Hans Peter (2001) "Carbenes in Matrices: Specrospcopy, Structure, and Photochemical Behavior". In Udo H. Brinker (ed.), Advances in carbene chemistry, p. 135. Elsevier. Template:ISBN
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  22. Günther Maier, Hans Peter Reisenauer, Heinz Balli, Willy Brandt, Rudolf Janoschek (1990): "C4O2 (1,2,3-Butatriene-1,4-dione), the First Dioxide of Carbon with an Even Number of C Atoms". Angewandte Chemie (International Edition in English), volume 29, issue 8, Pages 905–908.
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  24. a b c Eastwood, Frank W. (1997), Gas Phase Pyrolytic Methods for the Preparation of Carbon-Hydrogen and Carbon-Hydrogen-Oxygen Compounds.. In Yannick ValléeGas Phase Reactions in Organic Synthesis.CRC Press. Template:ISBN
  25. Reusch, Roman (2005). Absorptionsspektroskopie von langen Kohlenstoff-Kettenmolekülen und deren Oxide in kryogenen Matrizen. Thesis, Ruprecht-Karls-Universität Heidelberg (in German)
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  34. Leopold Gmelin (1825), Ueber einige merkwürdige, bei der Darstellung des Kaliums nach der Brunner'schen Methode, erhaltene Substanzen. Poggendorfs Annalen der Physik und Chemie, volume 4, p. 31. Online version accessed on 2009-07-08.
  35. Heller, Johann Florian (1837), Die Rhodizonsäure, eine aus den Produkten der Kaliumbereitung gewonnene neue Säure, und ihre chemischen Verhältnisse, Justus Liebigs Annalen der Pharmacie, volume 24, issue 1, pp. 1–16. Online version accessed on 2009-07-08.
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