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Peroxy acid

Organic acid having a peroxide bond

Aperoxy acid (often spelled as one word, peroxyacid, and sometimes called peracid) is an acid which contains an acidic –OOH group. The two main classes are those derived from conventional mineral acids, especially sulfuric acid, and the peroxy derivatives of organic carboxylic acids. They are generally strong oxidizers.

Peroxymonosulfuric acid (Caro's acid) is probably the most important inorganic peracid, at least in terms of its production scale.^[1] It is used for the bleaching of pulp and for the detoxification of cyanide in the mining industry. It is produced by treating sulfuric acid with hydrogen peroxide. Peroxymonophosphoric acid (H₃PO₅) is prepared similarly.^[2]

Some peroxy acids are only hypothetical, but their anions are known. This is the case for peroxycarbonate^[3] and perborate (see sodium perborate).^[4]

Several organic peroxyacids are commercially useful.^[5] They can be prepared in several ways. Most commonly, peracids are generated by treating the corresponding carboxylic acid with hydrogen peroxide:^[6]

RCO₂H + H₂O₂ ⇌ RCO₃H + H₂O

A related reaction involves treatment of the carboxylic anhydride:

(RCO)₂O + H₂O₂ → RCO₃H + RCO₂H

This method is popular for converting cyclic anhydrides to the corresponding monoperoxyacids, for example monoperoxyphthalic acid.
The third method involves treatment of acid chlorides:

RC(O)Cl + H₂O₂ → RCO₃H + HCl

meta-Chloroperoxybenzoic acid (mCPBA) is prepared in this way.^[7]

A related method starts with the peroxyanhydride.^[8]

Aromatic aldehydes can be autoxidized to give peroxycarboxylic acids:

Ar-CHO + O₂ → Ar-COOOH (Ar = aryl group)

The products, however, react with the initial aldehyde forming the carboxylic acid:

Ar-COOOH + Ar-CHO → 2 Ar-COOH

In terms of acidity, peroxycarboxylic acids are about 1000 times weaker than the parent carboxylic acid, due to the absence of resonance stabilization of the anion. For similar reasons, their pK_a values tend also to be relatively insensitive to substituents.

The most common use of organic peroxy acids is for the conversion of alkenes to epoxides, the Prilezhaev reaction. Another common reaction is conversion of cyclic ketones to the ring-expanded esters using peracids in a Baeyer-Villiger oxidation. They are also used for the oxidation of amines and thioetherstoamine oxides and sulfoxides. The laboratory applications of the valued reagent mCPBA illustrate these reactions.

Reaction of peroxycarboxylic acids with acid chlorides affords diacyl peroxides:

RC(O)Cl + RC(O)O₂H → (RC(O))₂O₂ + HCl

The oxidizing tendency of peroxides is related to the electronegativity of the substituents. Electrophilic peroxides are stronger oxygen-atom transfer agents. The oxygen-atom donor tendency correlates with the acidity of the O−H bond. Thus, the order of oxidizing power is CF₃CO₃H >CH₃CO₃H >H₂O₂.

Peroxycarboxylic acids are available in both solid and liquid forms. Due to their oxidizing and disinfecting properties, they can be used in both professional and domestic settings.^[9]

Peroxycarboxylic acids are bleaching agents and are used globally, particularly for tooth whitening. They are employed in various concentrations in dentistry to effectively bleach teeth. Lower concentrations are common for home use. Compared to hydrogen peroxide, peroxycarboxylic acids are approved as cosmetics in Europe under Regulation (EC) No. 1223/2009 of the European Parliament.^[10]

In healthcare, peroxycarboxylic acids are primarily used for wound disinfection and cleaning contact lenses.

Peroxycarboxylic acids are also found in cleaning agents, disinfectants, and detergents, as they reliably kill germs and bacteria.

• Organic peroxide
• Peracetic acid
• Peroxyacyl nitrates