The chemistry of aniline is rich because the compound has been cheaply available for many years. Below are some classes of its reactions.
Oxidation , a colorless liquid when pure, illustrating the tendency of anilines to air-oxidize to dark-colored products. The oxidation of aniline has been heavily investigated, and can result in reactions localized at nitrogen or more commonly results in the formation of new C-N bonds. In alkaline solution,
azobenzene results, whereas
arsenic acid produces the violet-coloring matter violaniline.
Chromic acid converts it into
quinone, whereas
chlorates, in the presence of certain metallic salts (especially of
vanadium), give
aniline black. Hydrochloric acid and potassium chlorate give
chloranil.
Potassium permanganate in neutral solution oxidizes it to
nitrobenzene; in alkaline solution to
azobenzene, ammonia, and
oxalic acid; in acid solution to aniline black.
Hypochlorous acid gives
4-aminophenol and para-amino
diphenylamine. Oxidation with
persulfate affords a variety of
polyanilines. These polymers exhibit rich redox and acid-base properties. s can form upon oxidation of aniline.
Electrophilic reactions at ortho- and para- positions Like
phenols, aniline derivatives are highly susceptible to
electrophilic substitution reactions. Its high reactivity reflects that it is an
enamine, which enhances the electron-donating ability of the ring. For example, reaction of aniline with
sulfuric acid at 180 °C produces
sulfanilic acid, . If bromine water is added to aniline, the
bromine water is decolourised and a white
precipitate of
2,4,6-tribromoaniline is formed. To generate the mono-substituted product, a
protection with acetyl chloride is required: The reaction to form
4-bromoaniline is to protect the amine with acetyl chloride, then hydrolyse back to reform aniline. The largest scale industrial reaction of aniline involves its alkylation with
formaldehyde. An idealized equation is shown: : The resulting diamine is the precursor to
4,4'-MDI and related diisocyanates.
Reactions at nitrogen Basicity Aniline is a weak
base.
Aromatic amines such as aniline are, in general, much weaker bases than
aliphatic amines. Aniline reacts with strong acids to form the
anilinium (or phenylammonium) ion (). Traditionally, the weak basicity of aniline is attributed to a combination of inductive effect from the more electronegative sp2 carbon and resonance effects, as the lone pair on the nitrogen is partially delocalized into the pi system of the benzene ring. (see the picture below): Missing in such an analysis is consideration of
solvation. Aniline is, for example, more basic than ammonia in the gas phase, but ten thousand times less so in aqueous solution.
Acylation Aniline reacts with
acyl chlorides such as
acetyl chloride to give
amides. The amides formed from aniline are sometimes called
anilides, for example is
acetanilide. At high temperatures aniline and carboxylic acids react to give the anilides.
N-Alkylation N-Methylation of aniline with
methanol at elevated temperatures over
acid catalysts gives
N-methylaniline and
N,N-dimethylaniline: :
N-Methylaniline and
N,
N-dimethylaniline are colorless liquids with
boiling points of 193–195 °C and 192 °C, respectively. These derivatives are of importance in the color industry.
Carbon disulfide derivatives Boiled with
carbon disulfide, it gives sulfocarbanilide (diphenyl
thiourea) (), which may be decomposed into phenyl
isothiocyanate (), and triphenyl
guanidine ().
Diazotization Aniline and its ring-substituted derivatives react with
nitrous acid to form
diazonium salts. One example is
benzenediazonium tetrafluoroborate. Through these intermediates, the amine group can be converted to a
hydroxyl (),
cyanide (), or
halide group (, where X is a
halogen) via
Sandmeyer reactions. This diazonium salt can also be reacted with Sodium nitrite| and
phenol to produce a
dye known as
benzeneazophenol, in a process called
coupling. The reaction of converting
primary aromatic amine into diazonium salt is called diazotisation. In this reaction primary aromatic amine is allowed to react with
sodium nitrite and 2 moles of
HCl, which is known as "ice cold mixture" because the temperature for the reaction was as low as 0.5 °C. The benzene diazonium salt is formed as major product alongside the byproducts
water and
sodium chloride.
Other reactions It reacts with nitrobenzene to produce
phenazine in the
Wohl–Aue reaction. Hydrogenation gives
cyclohexylamine. Being a standard reagent in laboratories, aniline is used for many niche reactions. Its acetate is used in the
aniline acetate test for carbohydrates, identifying pentoses by conversion to
furfural. It is used to stain neural
RNA blue in the
Nissl stain. In addition, aniline is the starting component in the production of
diglycidyl aniline.
Epichlorohydrin is the other main ingredient. ==Uses==