Carbon–hydrogen bond explained

In chemistry, the carbon-hydrogen bond ( bond) is a chemical bond between carbon and hydrogen atoms that can be found in many organic compounds. This bond is a covalent, single bond, meaning that carbon shares its outer valence electrons with up to four hydrogens. This completes both of their outer shells, making them stable.[1]

Carbon–hydrogen bonds have a bond length of about 1.09 Å (1.09 × 10−10 m) and a bond energy of about 413 kJ/mol (see table below). Using Pauling's scale—C (2.55) and H (2.2)—the electronegativity difference between these two atoms is 0.35. Because of this small difference in electronegativities, the bond is generally regarded as being non-polar. In structural formulas of molecules, the hydrogen atoms are often omitted. Compound classes consisting solely of bonds and bonds are alkanes, alkenes, alkynes, and aromatic hydrocarbons. Collectively they are known as hydrocarbons.

In October 2016, astronomers reported that the very basic chemical ingredients of life—the carbon-hydrogen molecule (CH, or methylidyne radical), the carbon-hydrogen positive ion and the carbon ion —are the result, in large part, of ultraviolet light from stars, rather than in other ways, such as the result of turbulent events related to supernovae and young stars, as thought earlier.[2]

Bond length

The length of the carbon-hydrogen bond varies slightly with the hybridisation of the carbon atom. A bond between a hydrogen atom and an sp2 hybridised carbon atom is about 0.6% shorter than between hydrogen and sp3 hybridised carbon. A bond between hydrogen and sp hybridised carbon is shorter still, about 3% shorter than sp3 C-H. This trend is illustrated by the molecular geometry of ethane, ethylene and acetylene.

Comparison of bond lengths in simple hydrocarbons[3]
MoleculeMethaneEthaneEthyleneAcetylene
FormulaCH4C2H6C2H4C2H2
Classalkanealkanealkenealkyne
Structure
Hybridisation of carbonsp3sp3sp2sp
C-H bond length1.087 Å1.094 Å1.087 Å1.060 Å
Proportion of ethane C-H bond length99%100%99%97%
Structure determination methodmicrowave spectroscopymicrowave spectroscopymicrowave spectroscopyinfrared spectroscopy

Reactions

See main article: Carbon–hydrogen bond activation. The C−H bond in general is very strong, so it is relatively unreactive. In several compound classes, collectively called carbon acids, the C−H bond can be sufficiently acidic for proton removal. Unactivated C−H bonds are found in alkanes and are not adjacent to a heteroatom (O, N, Si, etc.). Such bonds usually only participate in radical substitution. Many enzymes are known, however, to effect these reactions.[4]

Although the C−H bond is one of the strongest, it varies over 30% in magnitude for fairly stable organic compounds, even in the absence of heteroatoms.[5] [6]

BondHydrocarbon radicalMolar Bond Dissociation Energy (kcal)Molar Bond Dissociation Energy (kJ)
CH3−HMethyl104440
C2H5−HEthyl98410
(CH3)2HC−HIsopropyl95400
(CH3)3C−Htert-Butyl93390
CH2=CH−Hvinyl112470
HC≡C−Hethynyl133560
C6H5−Hphenyl110460
CH2=CHCH2−HAllyl88370
C6H5CH2−HBenzyl85360
OC4H7−Htetrahydrofuranyl92380
CH3C(O)CH2−Hacetonyl96400

See also

Notes and References

  1. Web site: Life Sciences Cyberbridge . Covalent Bonds . 2015-09-15 . dead . https://web.archive.org/web/20150918064547/http://cyberbridge.mcb.harvard.edu/bonding_3.html . 2015-09-18 .
  2. Web site: Landau . Elizabeth . Building Blocks of Life's Building Blocks Come From Starlight . 12 October 2016 . . 13 October 2016 .
  3. [CRC Handbook of Chemistry and Physics]
  4. Bollinger, J. M. Jr., Broderick, J. B. "Frontiers in enzymatic C-H-bond activation" Current Opinion in Chemical Biology 2009, vol. 13, page 51-7.
  5. Web site: Bond Energies. Organic Chemistry, Michigan State University. https://web.archive.org/web/20160829213457/http://www.cem.msu.edu/~reusch/OrgPage/bndenrgy.htm. 29 August 2016.
  6. Yu-Ran Luo and Jin-Pei Cheng "Bond Dissociation Energies" in CRC Handbook of Chemistry and Physics, 96th Edition