Chemistry:Oxocarbon anion

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Short description: Negatively-charged molecule made of carbon and oxygen
2D diagram of mellitate C
12O6−
12, one of the oxocarbon anions. Black circles are carbon atoms, red circles are oxygen atoms. Each blue halo represents one half of a negative charge.

In chemistry, an oxocarbon anion is a negative ion consisting solely of carbon and oxygen atoms, and therefore having the general formula CxOny for some integers x, y, and n.

The most common oxocarbon anions are carbonate, CO2−
3, and oxalate, C
2O2−
4. There are however a large number of stable anions in this class, including several ones that have research or industrial use. There are also many unstable anions, like CO
2 and CO4−, that have a fleeting existence during some chemical reactions; and many hypothetical species, like CO4−
4, that have been the subject of theoretical studies but have yet to be observed.

Stable oxocarbon anions form salts with a large variety of cations. Unstable anions may persist in very rarefied gaseous state, such as in interstellar clouds. Most oxocarbon anions have corresponding moieties in organic chemistry, whose compounds are usually esters. Thus, for example, the oxalate moiety [–O–(C=O)
2–O–] occurs in the ester dimethyl oxalate H
3C–O–(C=O)
2–O–CH
3.

Electronic structure of the carbonate ion

Space-filling model of the carbonate ion

The carbonate ion has a trigonal planar structure, point group D3h. The three C-O bonds have the same length of 136 pm and the 3 O-C-O angles are 120°. The carbon atom has 4 pairs of valence electrons, which shows that the molecule obeys the octet rule. This is one factor that contributes to the high stability of the ion, which occurs in rocks such as limestone. The electronic structure is described by two main theories which are used to show how the 4 electron pairs are distributed in a molecule that only has 3 C-O bonds.

With valence bond theory the electronic structure of the carbonate ion is a resonance hybrid of 3 canonical forms.

Carbonate-ion-resonance-2D.pngDelocalisation and partial charges on the carbonate ion

In each canonical form there are two single bonds one double bond. The three canonical forms contribute equally to the resonance hybrid, so the three bond C-O bonds have the same length.

making a π-bond between 2 atoms of the same chemical element

With molecular orbital theory the 3-fold axis is designated as the z axis of the molecule. Three σ bonds are formed overlap of the s, px and py orbitals on the carbon atom with a p orbital on each oxygen atom. In addition, a delocalized π bond is made by overlap of the pz orbital on the carbon atom with the pz orbital on each oxygen atom which is perpendicular to the plane of the molecule.

Note that the same bonding schemes may be applied the nitrate ion, NO3, which is isoelectronic with the carbonate ion.

Similarly, the two-fold symmetrical structure of a carboxylate group,CO2, may be described as a resonance hybrid of two canonical forms in valence bond theory, or with 2 σ bonds and a delocalized π bond in molecular orbital theory.

Related compounds

Oxocarbon acids

An oxocarbon anion CxOny can be seen as the result of removing all protons from a corresponding acid CxHnOy. Carbonate CO2−3, for example, can be seen as the anion of carbonic acid H2CO3. Sometimes the "acid" is actually an alcohol or other species; this is the case, for example, of acetylenediolate C2O2−2 that would yield acetylenediol C2H2O2. However, the anion is often more stable than the acid (as is the case for carbonate);[1] and sometimes the acid is unknown or is expected to be extremely unstable (as is the case of methanetetracarboxylate C(COO)4).

Neutralized species

Every oxocarbon anion CxOny can be matched in principle to the electrically neutral (or oxidized) variant CxOy, an oxocarbon (oxide of carbon) with the same composition and structure except for the negative charge. As a rule, however, these neutral oxocarbons are less stable than the corresponding anions. Thus, for example, the stable carbonate anion corresponds to the extremely unstable neutral carbon trioxide CO3;[2] oxalate C2O2−4 correspond to the even less stable 1,2-dioxetanedione C2O4;[3] and the stable croconate anion C5O2−5 corresponds to the neutral cyclopentanepentone C5O5, which has been detected only in trace amounts.[4]

Reduced variants

Conversely, some oxocarbon anions can be reduced to yield other anions with the same structural formula but greater negative charge. Thus rhodizonate C6O2−6 can be reduced to the tetrahydroxybenzoquinone (THBQ) anion C6O4−6 and then to benzenehexolate C6O6−6.[5]

Acid anhydrides

An oxocarbon anion CxOny can also be associated with the anhydride of the corresponding acid. The latter would be another oxocarbon with formula CxOy−​n2; namely, the acid minus ​n2 water molecules H2O. The standard example is the connection between carbonate CO2−3 and carbon dioxide CO2. The correspondence is not always well-defined since there may be several ways of performing this formal dehydration, including joining two or more anions to make an oligomer or polymer. Unlike neutralization, this formal dehydration sometimes yields fairly stable oxocarbons, such as mellitic anhydride C12O9 from mellitate C12O6−12 via mellitic acid C12H6O12[6][7][8]

Hydrogenated anions

For each oxocarbon anion CxOny there are in principle n−1 partially hydrogenated anions with formulas HkCxO(nk)−y, where k ranges from 1 to n−1. These anions are generally indicated by the prefixes "hydrogen"-, "dihydrogen"-, "trihydrogen"-, etc. Some of them, however, have special names: hydrogencarbonate HCO3 is commonly called bicarbonate, and hydrogenoxalate HC2O4 is known as binoxalate.

The hydrogenated anions may be stable even if the fully protonated acid is not (as is the case of bicarbonate).

List of oxocarbon anions

Here is an incomplete list of the known or conjectured oxocarbon anions

Diagram Formula Name Acid Anhydride Neutralized
Chemfm carbonite 2neg.svg :CO2−2 carbonite C(OH)2 (carbonous acid) CO CO2
Chemfm carbonate 2neg.svg CO2−3 carbonate CH2O3 CO2 CO3
Chemfm peroxocarbonate 2neg.svg CO2−4 peroxocarbonate CO3 CO4
Chemfm orthocarbonate 4neg.svg CO4−4 orthocarbonate C(OH)4 methanetetrol CO2 CO4
Chemfm acetylene dioxide 2neg.svg C2O2−2 acetylenediolate C2H2O2 acetylenediol C2O2
Chemfm oxalate 2neg.svg C2O2−4 oxalate C2H2O4 C2O3, C4O6 C2O4
Chemfm dicarbonate 2neg.svg C2O2−5 dicarbonate C2H2O5 C2O4
Chemfm peroxodicarbonate 2neg.svg C2O2−6 peroxodicarbonate
Chemfm cyclopropanetrione 2neg.svg C3O2−3 deltate C3O(OH)2 C3O3
Chemfm mesoxalate 2neg.svg C3O2−5 mesoxalate C3H2O5
Chemfm acetylenedicarboxylate 2neg.svg C4O2−4 acetylenedicarboxylate C4H2O4
Chemfm cyclobutanetetrone 2neg.svg C4O2−4 squarate C4O2(OH)2 C4O4
Chemfm dioxosuccinate 2neg.svg C4O2−6 dioxosuccinate C4H2O6
Chemfm cyclopentanepentone 2neg.svg C5O2−5 croconate C5O3(OH)2 C5O5
Chemfm methanetetracarboxylate 4neg.svg C5O4−8 methanetetracarboxylate C5H4O8
Chemfm cyclohexanehexone 2neg.svg C6O2−6 rhodizonate C4O4(COH)2 C6O6
Chemfm cyclohexanehexone 4neg.svg C6O4−6 benzoquinonetetraolate; THBQ anion (CO)2(COH)4 THBQ C6O6
Chemfm cyclohexanehexone 6neg.svg C6O6−6 benzenehexolate C6(OH)6 benzenehexol C6O6
Chemfm ethylenetetracarboxylate 4neg.svg C6O4−8 ethylenetetracarboxylate C6H4O8 C6O6
Chemfm furantetracarboxylate 4neg.svg C8O4−9 furantetracarboxylate C8H4O9 C8O7
Chemfm benzoquinonetetracarboxylate 4neg.svg C10O4−10 benzoquinonetetracarboxylate C10H4O10 C10O8
Chemfm mellitate 6neg.svg C12O6−12 mellitate C6(COOH)6 C12O9

Several other oxocarbon anions have been detected in trace amounts, such as C6O6, a singly ionized version of rhodizonate.[9]

See also

References

  1. "Infrared and mass spectral studies of proton irradiated H2O + CO2 ice: evidence for carbonic acid", by Moore, M. H.; Khanna, R. K.
  2. DeMore W. B.; Jacobsen C. W. (1969). "Formation of carbon trioxide in the photolysis of ozone in liquid carbon dioxide". Journal of Physical Chemistry 73 (9): 2935–2938. doi:10.1021/j100843a026. 
  3. Herman F. Cordes; Herbert P. Richter; Carl A. Heller (1969). "Mass spectrometric evidence for the existence of 1,2-dioxetanedione (carbon dioxide dimer). Chemiluminescent intermediate". J. Am. Chem. Soc. 91 (25): 7209. doi:10.1021/ja01053a065. 
  4. Schröder, Detlef; Schwarz, Helmut; Dua, Suresh; Blanksby, Stephen J.; Bowie, John H. (May 1999). "Mass spectrometric studies of the oxocarbons CnOn (n = 3–6)". International Journal of Mass Spectrometry 188 (1–2): 17–25. doi:10.1016/S1387-3806(98)14208-2. Bibcode1999IJMSp.188...17S. 
  5. Haiyan Chen, Michel Armand, Matthieu Courty, Meng Jiang, Clare P. Grey, Franck Dolhem, Jean-Marie Tarascon, and Philippe Poizot (2009), "Lithium Salt of Tetrahydroxybenzoquinone: Toward the Development of a Sustainable Li-Ion Battery" J. Am. Chem. Soc., 131(25), pp. 8984–8988 doi:10.1021/ja9024897
  6. J. Liebig, F. Wöhler (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.
  7. "Über ein neues Kohlenoxyd C12O9 (A new carbon oxide C12O9)". Berichte der Deutschen Chemischen Gesellschaft 46: 813–815. 1913. doi:10.1002/cber.191304601105. https://zenodo.org/record/1426491. 
  8. Hans Meyer; Karl Steiner (1913). "Über ein neues Kohlenoxyd C12O9". Berichte der Deutschen Chemischen Gesellschaft 46: 813–815. doi:10.1002/cber.191304601105. https://zenodo.org/record/1426491. 
  9. Richard B. Wyrwas and Caroline Chick Jarrold (2006), "Production of C6O6 from Oligomerization of CO on Molybdenum Anions". J. Am. Chem. Soc. volume 128 issue 42, pages 13688–13689. doi:10.1021/ja0643927



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