s
Acid-base reactions Carboxylic acids react with
bases to form carboxylate salts, in which the
hydrogen of the
hydroxyl (–OH) group is replaced with a metal
cation. For example,
acetic acid found in
vinegar reacts with
sodium bicarbonate (baking soda) to form
sodium acetate,
carbon dioxide, and water: :
Conversion to esters, amides, anhydrides Widely practiced reactions convert carboxylic acids into
esters,
amides,
carboxylate salts,
acid chlorides, and
alcohols. Their conversion to
esters is widely used, e.g. in the production of
polyesters. Likewise, carboxylic acids are converted into
amides, but this conversion typically does not occur by direct reaction of the carboxylic acid and the amine. Instead esters are typical precursors to amides. The conversion of
amino acids into
peptides is a significant biochemical process that requires
ATP. Converting a carboxylic acid to an amide is possible, but not straightforward. Instead of acting as a nucleophile, an amine will react as a base in the presence of a carboxylic acid to give the ammonium
carboxylate salt. Heating the salt to above 100 °C will drive off water and lead to the formation of the amide. This method of synthesizing amides is industrially important, and has laboratory applications as well. In the presence of a strong acid catalyst, carboxylic acids can
condense to form acid anhydrides. The condensation produces water, however, which can hydrolyze the anhydride back to the starting carboxylic acids. Thus, the formation of the anhydride via condensation is an equilibrium process. Under acid-catalyzed conditions, carboxylic acids will react with alcohols to form
esters via the
Fischer esterification reaction, which is also an equilibrium process. Alternatively,
diazomethane can be used to convert an acid to an ester. While esterification reactions with diazomethane often give quantitative yields, diazomethane is only useful for forming methyl esters.
Conversion to acyl halides The hydroxyl group on carboxylic acids may be replaced with a chlorine atom using
thionyl chloride to give
acyl chlorides. In nature, carboxylic acids are converted to
thioesters.
Thionyl chloride can be used to convert carboxylic acids to their corresponding acyl chlorides. First, carboxylic acid
1 attacks thionyl chloride, and chloride ion leaves. The resulting
oxonium ion 2 is activated towards nucleophilic attack and has a good leaving group, setting it apart from a normal carboxylic acid. In the next step,
2 is attacked by chloride ion to give tetrahedral intermediate
3, a chlorosulfite. The tetrahedral intermediate collapses with the loss of
sulfur dioxide and chloride ion, giving protonated acyl chloride
4. Chloride ion can remove the proton on the carbonyl group, giving the acyl chloride
5 with a loss of
HCl.
Phosphorus(III) chloride (PCl3) and
phosphorus(V) chloride (PCl5) will also convert carboxylic acids to acid chlorides, by a similar mechanism. One equivalent of PCl3 can react with three equivalents of acid, producing one equivalent of H3PO3, or
phosphorus acid, in addition to the desired acid chloride. PCl5 reacts with carboxylic acids in a 1:1 ratio, and produces
phosphorus(V) oxychloride (POCl3) and hydrogen chloride (HCl) as byproducts.
Reactions with carbanion equivalents Carboxylic acids react with Grignard reagents and organolithiums to form ketones. The first equivalent of nucleophile acts as a base and deprotonates the acid. A second equivalent will attack the carbonyl group to create a
geminal alkoxide dianion, which is protonated upon workup to give the hydrate of a ketone. Because most ketone hydrates are unstable relative to their corresponding ketones, the equilibrium between the two is shifted heavily in favor of the ketone. For example, the equilibrium constant for the formation of
acetone hydrate from acetone is only 0.002. The carboxylic group is the most acidic in organic compounds.
Specialized reactions • As with all carbonyl compounds, the protons on the
α-carbon are labile due to
keto–enol tautomerization. Thus, the α-carbon is easily halogenated in the
Hell–Volhard–Zelinsky halogenation. • The
Schmidt reaction converts carboxylic acids to
amines. • Carboxylic acids are decarboxylated in the
Hunsdiecker reaction. • The
Dakin–West reaction converts an amino acid to the corresponding amino ketone. • In the
Barbier–Wieland degradation, a carboxylic acid on an aliphatic chain having a simple
methylene bridge at the alpha position can have the chain shortened by one carbon. The inverse procedure is the
Arndt–Eistert synthesis, where an acid is converted into acyl halide, which is then reacted with
diazomethane to give one additional methylene in the aliphatic chain. • Many acids undergo
oxidative decarboxylation.
Enzymes that catalyze these reactions are known as
carboxylases (
EC 6.4.1) and
decarboxylases (EC 4.1.1). • Carboxylic acids are reduced to
aldehydes via the
ester and
DIBAL, via the acid chloride in the
Rosenmund reduction and via the thioester in the
Fukuyama reduction. • In
ketonic decarboxylation carboxylic acids are converted to ketones. • Organolithium reagents (>2 equiv) react with carboxylic acids to give a dilithium 1,1-diolate, a stable
tetrahedral intermediate which decomposes to give a ketone upon acidic workup. • The
Kolbe electrolysis is an electrolytic, decarboxylative dimerization reaction. It gets rid of the carboxyl groups of two acid molecules, and joins the remaining fragments together. ==Carboxyl radical==