,according to IUPAC: Butanenitrile (
blue marked C atom belongs to the main chain),formally also propanecarbonitrile (
blue marked C atom belongs to the substituent) The functional group of nitriles containing the triple bond is referred to as the nitrile or cyano group. If the nitrile is the highest-ranking
functional group, the suffix
-nitrile is added to the name of the parent compound. The triply bonded carbon atom is, as always, included in the parent chain. Alternatively, the ending
-carbonitrile may be used (analogous to
-carboxylic acid), in which case the carbon atom is
not counted as part of the parent chain. This ending must be used if the nitrile group is attached to a ring (as in ) or if not all carbon atoms are part of the parent chain, which is necessarily the case when more than two nitrile groups are present, as these can only be located at the termini of the chain. Due to their relationship to carboxylic acids (the nitrile carbon has the same oxidation state as the carboxyl carbon),
trivial names are often derived from the corresponding carboxylic acids using the ending
-onitrile (for example,
benzoic acid to
benzonitrile). If the nitrile function is
not the principal functional group in the molecule, the prefix
cyano- is used together with the appropriate
locant. In this case as well, the triple-bonded carbon atom is
not counted as part of the parent chain. An example of the Kolbe nitrile synthesis is the reaction of
methyl iodide with sodium cyanide to yield
acetonitrile and
sodium iodide: \mathrm{CH_3I + NaCN \longrightarrow CH_3CN + NaI} Similarly,
1,3-dibromopropane reacts with sodium cyanide to form
glutaronitrile, and
1-iodooctane reacts with potassium cyanide to give
nonannitrile. Cyanations can also be carried out using hydrogen cyanide in combination with
triethylaluminum or with
diethylaluminum cyanide; for example, in the ring opening of an
epoxide to a β-cyanohydrin or in the 1,4-addition of cyanide to an
enone.
Trimethylsilylcyanide is another cyanating reagent capable of opening epoxides to β-cyanohydrins, with concomitant silylation of the oxygen atom. Trimethylsilyl cyanide also enables substitution of tertiary alkyl halides, which is not feasible under Kolbe nitrile synthesis conditions. An important industrial process is the hydrocyanation of
butadiene to
adiponitrile. and
thionyl chloride (). In a related dehydration,
secondary amides give nitriles by the
von Braun amide degradation. In this case, one C-N bond is cleaved. : Specifically,
carboxamides and
oximes can be converted to nitriles by
dehydration (elimination of water). Numerous reagents and methodologies are available for this transformation. Methods for nitrile synthesis via dehydration of
nitroalkanes have also been described.
Phosphorus pentoxide, known since the mid-19th century, is a classical reagent for amide dehydration.
thionyl chloride, or
phosgene. In the presence of specific
palladium complexes or other suitable catalysts, acetonitrile can function as a dehydrating agent, converting an amide into a nitrile while being transformed into
acetamide. Similarly,
dichloroacetonitrile may be employed. Related systems utilize
iron(II) chloride tetrahydrate,
zinc trifluoromethanesulfonate, or
uranyl nitrate as catalysts in combination with
N-methyl-N-trimethylsilyltrifluoroacetamide as the dehydrating reagent. Carboxylic acid amides can also be dehydrated using a system comprising
triphenylphosphane,
iodine, and
4-methylmorpholine. Another approach involves high-temperature dehydration (220–240 °C) in
hexamethylphosphoramide (HMPA). Dehydration of primary amides with
zinc chloride under
microwaves is reversible. In aqueous acetonitrile, an amide can be converted to a nitrile; however, in a water–
tetrahydrofuran system with added acetamide, the reverse conversion of nitrile to amide occurs. Both carboxamides and aldoximes can be dehydrated using
aluminum chloride and
sodium iodide in acetonitrile. Conversion to nitriles under catalysis by heptavalent
rhenium species (
perrhenic acid or
trimethylsilyl perrhenate) is effective for both amides and aldoximes; the water formed can be removed by
azeotropic distillation. The conversion of
aldehydes to nitriles via
aldoximes is a popular laboratory route. Aldehydes react readily with
hydroxylamine salts, sometimes at temperatures as low as ambient, to give aldoximes. These can be dehydrated to nitriles by simple heating, although a wide range of reagents may assist with this, including
triethylamine/
sulfur dioxide,
zeolites, or
sulfuryl chloride. The related
hydroxylamine-O-sulfonic acid reacts similarly. :.) In specialised cases the
Van Leusen reaction can be used. Biocatalysts such as
aliphatic aldoxime dehydratase are also effective. Aldoximes may also be dehydrated with
cyanuric chloride, the
Burgess reagent, or a combination of
trifluoromethanesulfonic acid anhydride and triphenylphosphine, the latter being oxidized to
triphenylphosphine oxide. Catalytic dehydrogenation is likewise possible, for example with ,
copper(II) acetate, mixed hydroxides of
tin and
tungsten, or a bimetallic palladium–
manganese catalyst. Enzymatic dehydration of aldoximes using
aldoxime dehydratases has also been achieved. These bacterial enzymes, including those from
Pseudomonas chlororaphis, have been applied repeatedly in nitrile synthesis.
Preparation from aldehydes and ketones Aldehydes can be converted into oximes using
hydroxylamine hydrochloride and subsequently dehydrated to nitriles (e.g., with oxalyl chloride). Direct transformation of aldehydes to nitriles is also possible using
hydroxylamine-O-sulfonic acid or . Such conversions can also be accomplished with hydroxylamine in the presence of
titanium(IV) chloride or mixed tin–tungsten hydroxides as catalysts, or by addition of
sulfuryl fluoride or
selenium dioxide.
Tosylmethylisocyanide (Van Leusen reagent) enables direct conversion of ketones into nitriles via the
Van Leusen reaction, introducing the entire nitrile group and thus an additional carbon atom.
Oxidation of primary amines Numerous traditional methods exist for nitrile preparation by
amine oxidation. Common methods include the use of
potassium persulfate,
Trichloroisocyanuric acid, or
anodic electrosynthesis. In addition, several selective methods have been developed in the last decades for
electrochemical processes. Several procedures employ nitroxyl radicals such as
TEMPO or
4-acetamido-TEMPO as catalytic oxidants. These catalysts can be regenerated either by
potassium peroxymonosulfate as the stoichiometric oxidant or electrochemically under applied potential. Another approach utilizes
copper(I) chloride or
copper(II) chloride as catalyst, molecular oxygen as the stoichiometric oxidant, and a
molecular sieve to remove the water formed.
Ammoxidation In
ammoxidation, a
hydrocarbon is partially
oxidized in the presence of
ammonia. This conversion is practiced on a large scale for
acrylonitrile: :2 + 3 In the production of acrylonitrile, a side product is
acetonitrile. On an industrial scale, several derivatives of
benzonitrile,
phthalonitrile, as well as Isobutyronitrile are prepared by ammoxidation. The process is catalysed by
metal oxides and is assumed to proceed via the imine.
Ammoxidation is a heterogeneously catalyzed gas-phase reaction in which aliphatic or methyl-substituted aromatic compounds react with oxygen (air) and
ammonia to form nitriles, with water as a by-product. Reaction temperatures exceed 300 °C, and oxides of
vanadium,
chromium, or
molybdenum serve as catalysts.
Acrylonitrile, an important precursor for
polymer production (see Use section), is primarily manufactured by ammoxidation of
propene.
Preparation of aromatic nitriles Aryl nitriles can be synthesized via the
Sandmeyer reaction of
diazonium salts with
copper(I) cyanide or by the
Rosenmund-von Braun reaction (direct reaction of an aryl bromide with copper(I) cyanide). Conversion of
thiocyanate with aromatic carboxylic acids, known as
Letts nitrile synthesis, can be carried out using
potassium thiocyanate;
lead thiocyanate generally provides higher yields. Another palladium-catalyzed route (also employing Pd(PPh3)4) is the
decarbonylation of aromatic
acyl cyanides. Palladium-catalyzed cyanation of aryl chlorides with
potassium cyanide or
potassium hexacyanidoferrate(II) has likewise been reported.
Quinones can react with trimethylsilyl cyanide to give silylated cyanohydrins, which are subsequently aromatized using
phosphorus tribromide. A further approach involves reaction of aryl Grignard or aryllithium reagents with
dimethylmalonitrile. Aromatic nitriles are often prepared in the laboratory from the aniline via
diazonium compounds. This is the
Sandmeyer reaction. It requires transition metal cyanides. :
Preparation of cyanohydrins The
cyanohydrins are a special class of nitriles. Classically they result from the addition of alkali metal cyanides to aldehydes in the
cyanohydrin reaction. Because of the polarity of the organic carbonyl, this reaction requires no catalyst, unlike the hydrocyanation of alkenes. O-Silyl cyanohydrins are generated by the addition
trimethylsilyl cyanide in the presence of a catalyst (silylcyanation). Cyanohydrins are also prepared by transcyanohydrin reactions starting, for example, with
acetone cyanohydrin as a source of HCN. Cyanohydrins can also be prepared by addition of an alkali cyanide to an
aldehyde or
ketone in the presence of
acetic acid. For less reactive substrates,
diethylaluminum cyanide provides a suitable alternative. Another approach is transhydrocyanation, in which hydrogen cyanide is transferred from
acetone cyanohydrin to an aldehyde or ketone. Addition of
trimethylsilyl cyanide to aldehydes or ketones affords cyanohydrins as their trimethylsilyl ethers. Suitable catalysts include
zinc iodide, potassium cyanide in combination with
18-crown-6, or
ytterbium(III) cyanide.
Preparation of acyl cyanides Acyl cyanides (α-oxonitriles) can in certain cases be prepared by reacting
carboxylic acid halides with transition metal cyanides (e.g.,
copper cyanide or
silver cyanide). This approach is particularly effective for aromatic carboxylic acid halides and aliphatic acyl bromides, whereas aliphatic acyl chlorides are unreactive. Aliphatic acyl cyanides can instead be synthesized by reacting carboxylic acid chlorides with trimethylsilyl cyanide.
Enantioselective synthesis of chiral nitriles Using
chiral pool starting materials,
enantioselective synthesis enables access to α-
chiral nitrile-containing compounds in
eutomeric form, such as
vildagliptin and
saxagliptin. Conventional transformations can introduce the nitrile functionality; for example, an enantiomerically pure amide or oxime derived from naturally enantiopure
proline may be dehydrated. The applicability of such strategies depends on the specific target molecule. Asymmetric cyanation reactions are also established. Of particular importance is the asymmetric hydrocyanation of carbonyl compounds (see section on cyanohydrin preparation). In addition, numerous asymmetric hydrocyanations of imines have been developed, affording enantiomerically pure α-aminonitriles. It has been used in
nucleophilic addition to
ketones. For an example of its use see:
Kuwajima Taxol total synthesis • Cyanide ions facilitate the coupling of dibromides. Reaction of α,α′-dibromo
adipic acid with
sodium cyanide in
ethanol yields the cyano
cyclobutane: • Aromatic nitriles can be prepared from base hydrolysis of trichloromethyl aryl ketimines () in the Houben-Fischer synthesis •
α-
Amino acids form nitriles and
carbon dioxide via various means of
oxidative decarboxylation.
Henry Drysdale Dakin discovered this oxidation in 1916. • From aryl carboxylic acids (
Letts nitrile synthesis) •
Carbocyanation enables addition of a nitrile group across a multiple bond to yield a further nitrile. Aryl nitriles can be added to alkynes under catalysis by
bis(cyclooctadiene)nickel(0) and
trimethylphosphine, affording α,β-unsaturated nitriles. Modification of the reaction conditions, for example by employing a different
phosphane or adding a
frustrated Lewis pair such as trimethylaluminum or
triphenylborane, allows addition of non-aromatic nitriles, both saturated and α,β-unsaturated. Carbocyanation reactions that couple two molecules while introducing a nitrile group are also known, using
hexabutyldistannane and
tosyl cyanide as the cyanide source. • Carboxylic acids can be converted to the corresponding nitriles by reaction with
indium(III) chloride in acetonitrile at 200 °C. In this process, acetonitrile functions both as solvent and nitrogen source and is converted into
acetic acid. The reaction proceeds via multiple
Mumm rearrangements. Alcohols can be transformed into nitriles by a
Mitsunobu reaction, employing
cyanomethylidene trimethyl phosphorane in the presence of acetone cyanohydrin.
N-Alkylamides can be converted to nitriles via the
von Braun degradation using
phosphorus pentachloride. Alternative reagents include
phosphorus pentabromide and
carbonyl bromide. == Reactions ==