Quick Search
CAS Number: 65-85-0
Benzoic acid was discovered in the sixteenth century.
The dry distillation of gum benzoin was first described by Nostradamus (1556), and then by Alexius Pedemontanus (1560) and Blaise de Vigenère (1596).
Justus von Liebig and Friedrich Wöhler determined the composition of benzoic acid. These latter also investigated how hippuric acid is related to benzoic acid.
In 1875 Salkowski discovered the antifungal abilities of benzoic acid, which was used for a long time in the preservation of benzoate-containing cloudberry fruits.
It is also one of the chemical compounds found in castoreum. This compound is gathered from the castor sacs of the North American beaver.
Synonyms: benzoic acid; BENZOIC ACID; benzoic acid; BENZOIC acid; benzoıc acıd; benzene carboxylic acid; Dracylic acid; benzenecarboxylic acid; Carboxybenzene; Benzeneformic acid; phenylformic acid; Benzenemethanoic acid; Phenylcarboxylic acid; Acide benzoique; Benzoesaeure; Benzoic acid, tech.; Kyselina benzoova; Benzoic acid (natural); Benzoate (VAN); Benzoesaeure [German]; Diacylic acid; Oracylic acid; Acide benzoique [French]; Acido benzoico [Italian]; Benzenemethonic acid; Kyselina benzoova [Czech]; Benzoic acid [USAN:JAN]; Benzoic acid Natural; Benzeneformate; Benzenemethanoate; Phenylcarboxylate; Benzenecarboxylate; Benzoicacid; (2H5)Benzoic acid; Carboxypolystyrene; Phenyl carboxylic acid; Benzoic acid, 99%, extra pure; Acido benzoico; benzoik asit; BENZOİK ASİT; benzoık asıt; BENZOIK ASIT; BENZOİK ACID; benzoik acid; Benzoik asit; benzoik asit; benzen karboksilik asit; Drasilik asit; benzenkarboksilik asit; Karboksibenzen; Benzeneformik asit; fenilformik asit; Benzenmetanoik asit; Fenilkarboksilik asit; Acide benzoique; Benzoesaeure; Benzoik asit, teknoloji .; Kyselina benzoova; Benzoik asit (doğal); Benzoat (VAN); Benzoesaeure [Almanca]; Diasilik asit; Orasilik asit; Acide benzoique [Fransızca]; Acido benzoico [İtalyanca]; Benzenemethonic asit; Kyselina benzoova [Çekçe]; Benzoik asit [USAN: JAN]; Benzoik asit Doğal; Benzeneformate; Benzenemethanoate; Fenilkarboksilat; Benzenecarboxylate; Benzoik asit; (2H5) Benzoik asit; Karboksipolistiren; Fenil karboksilik asit; Benzoik asit; Acido benzoico; ACIDE BENZOIQUE; acide benzoique; Acide benzoique; acide benzoique; acide benzène carboxylique; Acide dracylique; l'acide benzène-carboxylique; Carboxybenzène; Acide benzèneformique; acide phénylformique; Acide benzène-méthanoïque; Acide phénylcarboxylique; Acide benzoique; Benzoesaeure; Acide benzoïque, tech .; Kyselina benzoova; Acide benzoïque (naturel); Benzoate (VAN); Benzoesaeure [allemand]; Acide diacylique; Acide oracylique; Acide benzoique [français]; Acido benzoico [italien]; Acide benzéméthonique; Kyselina benzoova [tchèque]; Acide benzoïque [USAN: JAN]; Acide benzoïque naturel; Benzèneformate; Benzenemethanoate; Phénylcarboxylate; Benzenecarboxylate; Acide benzoique; (2H5) acide benzoïque; Carboxypolystyrène; Acide phénylcarboxylique; Acide benzoïque, 99%, extra pur; Acido benzoic; бензойная кислота; БЕНЗОЙНАЯ КИСЛОТА; бензойная кислота; Бензойная кислота; бензойная кислота; бензолкарбоновая кислота; Драциловая кислота; бензолкарбоновая кислота; Карбоксибензол; Бензолефорная кислота; фенилформиновая кислота; Бензолметановая кислота; Фенилкарбоновая кислота; Бензойная кислота; Бензоэфир; Бензойная кислота, техн .; Киселина бензова; Бензойная кислота (натуральная); Бензоат (Ван); Benzoesaeure [немецкий]; Диациловая кислота; Орациловая кислота; Бензойная кислота [французский язык]; Ацидо бензоико [итальянский]; Бензолметоновая кислота; Киселина бензова [чешский]; Бензойная кислота [USAN: JAN]; Бензойная кислота натуральная; Бензолформиат; Бензолметаноат; Фенилкарбоксилат; Бензолкарбоксилат; Бензойная кислота; бензойная кислота; Карбоксиполистирол; Фенилкарбоновая кислота; Бензойная кислота, 99%, особо чистая; Ацидо бензоико
Molecular Weight:122.12 g/mol
Hydrogen Bond Acceptor Count:2
Rotatable Bond Count:1
Exact Mass:122.036779 g/mol
Monoisotopic Mass:122.036779 g/mol
Topological Polar Surface Area: 37.3 Ų
Heavy Atom Count:9
Formal Charge:0
Complexity:104
Isotope Atom Count: 0
Defined Atom Stereocenter Count:0
Undefined Atom Stereocenter Count:0
Defined Bond Stereocenter Count:0
Covalently-Bonded Unit Count: 1
Compound Is Canonicalized: Yes
Benzoic Acid's:
Crystal structure:Monoclinic
Molecular shape:planar
Dipole moment:1.72 D in dioxane
Benzoic acid is a white (or colorless) solid with the formula C6H5CO2H.
It is the simplest aromatic carboxylic acid.
The name is derived from gum benzoin, which was for a long time its only source.
Benzoic acid occurs naturally in many plants and serves as an intermediate in the biosynthesis of many secondary metabolites.
Salts of benzoic acid are used as food preservatives.
Benzoic acid is an important precursor for the industrial synthesis of many other organic substances.
The salts and esters of benzoic acid are known as benzoates.
Production:
Industrial preparations
Benzoic acid is produced commercially by partial oxidation of toluene with oxygen.
The process is catalyzed by cobalt or manganese naphthenates. The process uses abundant materials, and proceeds in high yield.
The first industrial process involved the reaction of benzotrichloride (trichloromethyl benzene) with calcium hydroxide in water, using iron or iron salts as catalyst.
The resulting calcium benzoate is converted to benzoic acid with hydrochloric acid.
The product contains significant amounts of chlorinated benzoic acid derivatives.
For this reason, benzoic acid for human consumption was obtained by dry distillation of gum benzoin.
Food-grade benzoic acid is now produced synthetically.
Laboratory synthesis:
Benzoic acid is cheap and readily available, so the laboratory synthesis of benzoic acid is mainly practiced for its pedagogical value.
It is a common undergraduate preparation.
Benzoic acid can be purified by recrystallization from water because of its high solubility in hot water and poor solubility in cold water.
The avoidance of organic solvents for the recrystallization makes this experiment particularly safe.
This process usually gives a yield of around 65%.
By hydrolysis:
Like other nitriles and amides, benzonitrile and benzamide can be hydrolyzed to benzoic acid or its conjugate base in acid or basic conditions.
From Grignard reagent:
Bromobenzene can be converted to benzoic acid by "carboxylation" of the intermediate phenylmagnesium bromide.
This synthesis offers a convenient exercise for students to carry out a Grignard reaction, an important class of carbon–carbon bond forming reaction in organic chemistry.
Oxidation of benzyl compounds:
Benzyl alcohol and benzyl chloride and virtually all benzyl derivatives are readily oxidized to benzoic acid.
Uses:
Benzoic acid is mainly consumed in the production of phenol by oxidative decarboxylation at 300−400 °C
C6H5CO2H + 1/2 O2 → C6H5OH + CO2
The temperature required can be lowered to 200 °C by the addition of catalytic amounts of copper (II) salts.
The phenol can be converted to cyclohexanol, which is a starting material for nylon synthesis.
Precursor to plasticizers:
Benzoate plasticizers, such as the glycol-, diethyleneglycol-, and triethyleneglycol esters, are obtained by transesterification of methyl benzoate with the corresponding diol. Alternatively these species arise by treatment of benzoyl chloride with the diol.
These plasticizers are used similarly to those derived from terephthalic acid ester.
Precursor to sodium benzoate and related preservatives
Benzoic acid and its salts are used as a food preservatives, represented by the E numbers E210, E211, E212, and E213.
Benzoic acid inhibits the growth of mold, yeast[24] and some bacteria.
It is either added directly or created from reactions with its sodium, potassium, or calcium salt.
The mechanism starts with the absorption of benzoic acid into the cell.
If the intracellular pH changes to 5 or lower, the anaerobic fermentation of glucose through phosphofructokinase is decreased by 95%.
The efficacy of benzoic acid and benzoate is thus dependent on the pH of the food.
Acidic food and beverage like fruit juice (citric acid), sparkling drinks (carbon dioxide), soft drinks (phosphoric acid), pickles (vinegar) or other acidified food are preserved with benzoic acid and benzoates.
Typical levels of use for benzoic acid as a preservative in food are between 0.05–0.1%.
Foods in which benzoic acid may be used and maximum levels for its application are controlled by local food laws.
Concern has been expressed that benzoic acid and its salts may react with ascorbic acid (vitamin C) in some soft drinks,
forming small quantities of carcinogenic benzene.
Medicinal:
Benzoic acid is a constituent of Whitfield's ointment which is used for the treatment of fungal skin diseases such as tinea, ringworm, and athlete's foot.
As the principal component of gum benzoin, benzoic acid is also a major ingredient in both tincture of benzoin and Friar's balsam.
Such products have a long history of use as topical antiseptics and inhalant decongestants.Benzoic acid was used as an expectorant, analgesic,
and antiseptic in the early 20th century.
Biology and health effects:
Benzoic acid occurs naturally as do its esters in many plant and animal species.
Appreciable amounts are found in most berries (around 0.05%). Ripe fruits of several Vaccinium species contain as much as 0.03–0.13% free benzoic acid.
Benzoic acid is also formed in apples after infection with the fungus Nectria galligena.
Among animals, benzoic acid has been identified primarily in omnivorous or phytophageous species, e.g., in viscera and muscles of the rock ptarmigan (Lagopus muta) as well as in gland secretions of male muskoxen (Ovibos moschatus) or Asian bull elephants (Elephas maximus).
Gum benzoin contains up to 20% of benzoic acid and 40% benzoic acid esters.
In terms of its biosynthesis, benzoate is produced in plants from cinnamic acid.A pathway has been identified from phenol via 4-hydroxybenzoate.
Safety and mammalian metabolism:
It is excreted as hippuric acid. Benzoic acid is metabolized by butyrate-CoA ligase into an intermediate product, benzoyl-CoA,which is then metabolized by glycine N-acyltransferase into hippuric acid. Humans metabolize toluene and benzoic acid which is excreted as hippuric acid.
For humans, the World Health Organization's International Programme on Chemical Safety (IPCS) suggests a provisional tolerable intake would be 5 mg/kg body weight per day. Cats have a significantly lower tolerance against benzoic acid and its salts than rats and mice.
Lethal dose for cats can be as low as 300 mg/kg body weight.The oral LD50 for rats is 3040 mg/kg, for mice it is 1940–2263 mg/kg.
In Taipei, Taiwan, a city health survey in 2010 found that 30% of dried and pickled food products had benzoic acid.
Safety and mammalian metabolism
It is excreted as hippuric acid.Benzoic acid is metabolized by butyrate-CoA ligase into an intermediate product, benzoyl-CoA,which is then metabolized by glycine N-acyltransferase into hippuric acid.Humans metabolize toluene and benzoic acid which is excreted as hippuric acid.
