Carbon compounds are defined as chemical substances containing carbon.[1][2] More compounds of carbon exist than any other chemical element except for hydrogen. Organic carbon compounds are far more numerous than inorganic carbon compounds. In general bonds of carbon with other elements are covalent bonds. Carbon is tetravalent but carbon free radicals and carbenes occur as short-lived intermediates. Ions of carbon are carbocations and carbanions are also short-lived. An important carbon property is catenation as the ability to form long carbon chains and rings.[3]

Allotropes of carbon

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The known inorganic chemistry of the allotropes of carbon (diamond, graphite, and the fullerenes) blossomed with the discovery of buckminsterfullerene in 1985, as additional fullerenes and their various derivatives were discovered. One such class of derivatives is inclusion compounds, in which an ion is enclosed by the all-carbon shell of the fullerene. This inclusion is denoted by the "@"symbol in endohedral fullerenes. For example, an ion consisting of a lithium ion trapped within buckminsterfullerene would be denoted Li+@C60. As with any other ionic compound, this complex ion could in principle pair with a counterion to form a salt. Other elements are also incorporated in so-called graphite intercalation compounds.

Carbides

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Carbides are binary compounds of carbon with an element that is less electronegative than it. The most important are Al4C3, B4C, CaC2, Fe3C, HfC, SiC, TaC, TiC, and WC.

Metal Structure of pure metal Metallic
radius (pm)
MC
metal atom packing
MC structure M2C
metal atom packing
M2C structure Other carbides
titanium hcp 147 ccp rock salt
zirconium hcp 160 ccp rock salt
hafnium hcp 159 ccp rock salt
vanadium bcc 134 ccp rock salt hcp h/2 V4C3
niobium bcc 146 ccp rock salt hcp h/2 Nb4C3
tantalum bcc 146 ccp rock salt hcp h/2 Ta4C3
chromium bcc 128 Cr23C6, Cr3C,
Cr7C3, Cr3C2
molybdenum bcc 139 hexagonal hcp h/2 Mo3C2
tungsten bcc 139 hexagonal hcp h/2

Organic compounds

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It was once thought that organic compounds could only be created by living organisms. Over time, however, scientists learned how to synthesize organic compounds in the lab. The number of organic compounds is immense and the known number of defined compounds is close to 10 million.[4] However, an indefinitely large number of such compounds is theoretically possible. By definition, an organic compound must contain at least one atom of carbon, but this criterion is not generally regarded as sufficient. Indeed, the distinction between organic and inorganic compounds is ultimately a matter of convention, and there are several compounds that have been classified either way, such as: COCl2, CSCl2, CS(NH2)2, CO(NH2)2. With carbon bonded to metals the field of organic chemistry crosses over into organometallic chemistry.


Carbon-oxygen compounds

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There are many oxides of carbon (oxocarbons), of which the most common are carbon dioxide (CO2) and carbon monoxide (CO). Other less known oxides include carbon suboxide (C3O2) and mellitic anhydride (C12O9).[5] There are also numerous unstable or elusive oxides, such as dicarbon monoxide (C2O), oxalic anhydride (C2O4), and carbon trioxide (CO3).

There are several oxocarbon anions, negative ions that consist solely of oxygen and carbon. The most common are the carbonate (CO32−) and oxalate (C2O42−). The corresponding acids are the highly unstable carbonic acid (H2CO3) and the quite stable oxalic acid (H2C2O4), respectively. These anions can be partially deprotonated to give the bicarbonate (HCO3) and hydrogenoxalate (HC2O4). Other more exotic carbon–oxygen anions exist, such as acetylenedicarboxylate (O2C–C≡C–CO22−), mellitate (C12O96−), squarate (C4O42−), and rhodizonate (C6O62−). The anhydrides of some of these acids are oxides of carbon; carbon dioxide, for instance, can be seen as the anhydride of carbonic acid.

Some important carbonates are Ag2CO3, BaCO3, CaCO3, CdCO3, Ce2(CO3)3, CoCO3, Cs2CO3, CuCO3, FeCO3, K2CO3, La2(CO3)3, Li2CO3, MgCO3, MnCO3, (NH4)2CO3, Na2CO3, NiCO3, PbCO3, SrCO3, and ZnCO3.

The most important bicarbonates include NH4HCO3, Ca(HCO3)2, KHCO3, and NaHCO3.

The most important oxalates include Ag2C2O4, BaC2O4, CaC2O4, Ce2(C2O4)3, K2C2O4, and Na2C2O4.

Carbonyls are coordination complexes between transition metals and carbonyl ligands. Metal carbonyls are complexes that are formed with the neutral ligand CO. These complexes are covalent. Here is a list of some carbonyls: Cr(CO)6, Co2(CO)8, Fe(CO)5, Mn2(CO)10, Mo(CO)6, Ni(CO)4, W(CO)6.

Carbon-sulfur compounds

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Important inorganic carbon-sulfur compounds are the carbon sulfides carbon disulfide (CS2) and carbonyl sulfide (OCS). Carbon monosulfide (CS) unlike carbon monoxide is very unstable. Important compound classes are thiocarbonates, thiocarbamates, dithiocarbamates and trithiocarbonates.

     
carbon monosulfide carbon disulfide carbonyl sulfide
Inorganic carbon-sulfur compounds

Carbon-nitrogen compounds

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Small inorganic carbon – nitrogen compounds are cyanogen, hydrogen cyanide, cyanamide, isocyanic acid and cyanogen chloride.

composition Molar mass (g/mole) Boiling point °C Melting point °C
cyanogen (CN)2   52.03 −21 −28
hydrogen cyanide HCN   27.03 25–26 −12 – -14
cyanamide CN2H2   42.04 260 (decomp.) 44
isocyanic acid HNCO   43.03 23.5 −86
cyanogen chloride CNCl   61.47 13 −6
chlorosulfonyl isocyanate CNClO3S   141.53 107 −44
cyanuric chloride (NCCl)3   184.41 192 154
Inorganic carbon-nitrogen compounds

Paracyanogen is the polymerization product of cyanogen. Cyanuric chloride is the trimer of cyanogen chloride and 2-cyanoguanidine is the dimer of cyanamide.

Other types of inorganic compounds include the inorganic salts and complexes of the carbon-containing cyanide, cyanate, fulminate, thiocyanate and cyanamide ions. Examples of cyanides are copper cyanide (CuCN) and potassium cyanide (KCN), examples of cyanates are potassium cyanate (KNCO) and silver cyanate (AgNCO), examples of fulminates are silver fulminate (AgOCN) and mercury fulminate (HgOCN) and an example of a thiocyanate is potassium thiocyanate (KSCN).

Carbon halides

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The common carbon halides are carbon tetrafluoride (CF4), carbon tetrachloride (CCl4), carbon tetrabromide (CBr4), carbon tetraiodide (CI4), and a large number of other carbon-halogen compounds.

Carboranes

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A carborane is a cluster composed of boron and carbon atoms such as H2C2B10H10.

Alloys

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There are hundreds of alloys that contain carbon. The most common of these alloys is steel, sometimes called "carbon steel" (see Category:Steels). All kinds of steel contain some amount of carbon, by definition, and all ferrous alloys contain some carbon.

Some other common alloys that are based on iron and carbon include anthracite iron, cast iron, pig iron, and wrought iron.

In more technical uses, there are also spiegeleisen, an alloy of iron, manganese, and carbon; and stellite, an alloy of cobalt, chromium, tungsten, and carbon.

Whether it was placed there deliberately or not, some traces of carbon is also found in these common metals and their alloys: aluminum, chromium, magnesium, molybdenum, niobium, thorium, titanium, tungsten, uranium, vanadium, zinc, and zirconium. For example, many of these metals are smelted with coke, a form of carbon; and aluminum and magnesium are made in electrolytic cells with carbon electrodes. Some distribution of carbon into all of these metals is inevitable.

References

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  1. ^ Organic Chemistry by Abraham William Simpson
  2. ^ Encyclopedia of Inorganic Chemistry Bruce King Ed. Second Edition
  3. ^ Advanced Inorganic Chemistry Cotton, F. Albert / Wilkinson, Geoffrey
  4. ^ Chemistry Operations (December 15, 2003). "Carbon". Los Alamos National Laboratory. Retrieved 2007-11-21.
  5. ^ It is an organic compound.