Nitroso

Template:Short description Script error: No such module "redirect hatnote".

In organic chemistry, nitroso refers to a functional group in which the nitric oxide (Template:Chem2) group is attached to an organic moiety. As such, various nitroso groups can be categorized as C-nitroso compounds (e.g., nitrosoalkanes; Template:Chem2), S-nitroso compounds (nitrosothiols; Template:Chem2), N-nitroso compounds (e.g., nitrosamines, Template:Chem2), and O-nitroso compounds (alkyl nitrites; Template:Chem2).

Synthesis

Script error: No such module "Labelled list hatnote". Nitroso compounds can be prepared by the reduction of nitro compounds^[1] or by the oxidation of hydroxylamines.^[2] Ortho-nitrosophenols may be produced by the Baudisch reaction. In the Fischer–Hepp rearrangement, aromatic 4-nitrosoanilines are prepared from the corresponding nitrosamines.

Properties

Nitrosoarenes typically participate in a monomer–dimer equilibrium. The azobenzene N,N'-dioxide (Ar(^–O)N⁺=⁺N(O^–)Ar) dimers, which are often pale yellow, are generally favored in the solid state, whereas the deep-green monomers are favored in dilute solution or at higher temperatures. They exist as cis and trans isomers.^[4] The central "double bond" in the dimer in fact has a bond order of about 1.5.^[5]

When stored in protic media, primary and secondary nitrosoalkanes isomerize to oximes.^[6] Some tertiary nitrosoalkanes also isomerize to oximes through C-C bond fission, particularly if the bond is electron-poor.Template:Sfn Nitrosophenols and naphthols isomerize to the oxime quinone in solution, but reversibly; nitrosophenol ethers typically dealkylate to facilitate the isomerization. Nitroso tertiary anilines generally do not dealkylate in that way.Template:Sfn

Due to the stability of the nitric oxide free radical, nitroso organyls tend to have very low C–N bond dissociation energies: nitrosoalkanes have BDEs on the order of Template:Cvt, while nitrosoarenes have BDEs on the order of Template:Cvt. As a consequence, they are generally heat- and light-sensitive. Compounds containing O–(NO) or N–(NO) bonds generally have even lower bond dissociation energies. For instance, N-nitrosodiphenylamine, Ph₂N–N=O, has a N–N bond dissociation energy of only Template:Cvt.^[7]

Organonitroso compounds serve as a ligands giving transition metal nitroso complexes.^[8]

Reactions

Many reactions make use of an intermediate nitroso compound, such as the Barton reaction and Davis–Beirut reaction, as well as the synthesis of indoles, for example: Baeyer–Emmerling indole synthesis, Bartoli indole synthesis. In the Saville reaction, mercury is used to replace a nitrosyl from a thiol group.

C-nitroso compounds are used in organic synthesis as synthons in some well-documented chemical reactions such as hetero Diels-Alder (HDA), nitroso-ene and nitroso-aldol reactions.^[9]

Nitrosyl in inorganic chemistry

Nitrosyls are non-organic compounds containing the NO group, for example directly bound to the metal via the N atom, giving a metal–NO moiety. Alternatively, a nonmetal example is the common reagent nitrosyl chloride (Template:Chem2). Nitric oxide is a stable radical, having an unpaired electron. Reduction of nitric oxide gives the nitrosyl anion, Template:Chem2:

Template:Chem2

Oxidation of NO yields the nitrosonium cation, Template:Chem2:

Template:Chem2

Nitric oxide can serve as a ligand forming metal nitrosyl complexes or just metal nitrosyls. These complexes can be viewed as adducts of Template:Chem2, Template:Chem2, or some intermediate case.

In human health

Template:Transcluded sectionNitrosamine formation during digestion

See also

• Nitrosamine, the functional group with the NO attached to an amine, such as R₂N–NO
• Nitrosobenzene
• Nitric oxide
• Nitroxyl

References

<templatestyles src="Reflist/styles.css" />

Script error: No such module "Check for unknown parameters".

Script error: No such module "Navbox". Template:Nitric oxide signaling Template:Nitrogen compounds Template:Authority control