Ester
From Wikipedia, the free encyclopedia
Esters are a class of chemical compounds and functional groups. Esters consist of an inorganic or organic acid in which at least one -OH (hydroxyl) group is replaced by an -O-alkyl (alkoxy) group. Some acids that are commonly esterified are carboxylic acids, phosphoric acid, sulfuric acid, nitric acid, and boric acid. Volatile esters, particularly carboxylate esters, often have a pleasant smell and are found in perfumes, essential oils, and pheromones, and give many fruits their scent. Ethyl acetate and methyl acetate are important solvents; fatty acid esters form fat and lipids; phosphoesters form the backbone of DNA molecules; and polyesters are important plastics. Cyclic esters are called lactones. The name "ester" is derived from the German Essig-Äther (literally: vinegar ether), an old name for ethyl acetate. Esters can be synthesized in a condensation reaction between an acid and an alcohol in a reaction known as esterification.
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[edit] Nomenclature
An ester is named according to the two parts that make it up: the part from the alcohol and the part from the acid (in that order), for example ethyl ethanoate (see image below).
Since most esters, or carbonate, are derived from carboxylic acids, a specific nomenclature is used for them. For esters derived from the simplest carboxylic acids, the traditional name for the acid constituent is generally retained, e.g., formate, acetate, propionate, butyrate.[1] For esters from more complex carboxylic acids, the systematic name for the acid is used, followed by the suffix -oate. For example, methyl formate is the ester of methanol and methanoic acid (formic acid): the simplest ester. It could also be called methyl methanoate.[2]
Esters of aromatic acids are also encountered, including benzoates such as methyl benzoate, and phthalates, with substitution allowed in the name.
[edit] Physical properties
Esters participate in hydrogen bonds as hydrogen-bond acceptors, but cannot act as hydrogen-bond donors, unlike their parent alcohols. This ability to participate in hydrogen bonding makes them more water-soluble than their parent hydrocarbons. However, the limitations on their hydrogen bonding also make them more hydrophobic than either their parent alcohols or their parent acids. Their lack of hydrogen-bond-donating ability means that ester molecules cannot hydrogen-bond to each other, which, in general, makes esters more volatile than a carboxylic acid of similar molecular weight. This property makes them very useful in organic analytical chemistry: Unknown organic acids with low volatility can often be esterified into a volatile ester, which can then be analyzed using gas chromatography, gas liquid chromatography, or mass spectrometry. Many esters have distinctive odors, which has led to their use as artificial flavorings and fragrances. For example:
[edit] Ester synthesis
"Esterification" (condensation of an alcohol and an acid) is not the only way to synthesize an ester. Esters can be prepared in the laboratory in a number of other ways:
- Transesterifications between other esters
- Dieckmann condensation or Claisen condensation of esters carrying acidic α-protons
- Favorskii rearrangement of α-haloketones in presence of base
- Nucleophilic displacement of alkyl halides with carboxylic acid salts
- Nucleophilic displacement of acyl halides with alcohols
- Baeyer-Villiger oxidation of ketones with peroxides
- Pinner reaction of nitriles with an alcohol
[edit] Ester reactions
Esters react in a number of ways:
- Esters may undergo hydrolysis - the breakdown of an ester by water. This process can be catalyzed both by acids and bases. The base-catalyzed process is called saponification. The hydrolysis yields an alcohol and a carboxylic acid or its carboxylate salt.
- Esters also react if heated with primary or secondary amines, producing amides.
- Phenyl esters react to hydroxyarylketones in the Fries rearrangement.
- Di-esters such as diethyl malonate react as nucleophile with alkyl halides in the malonic ester synthesis after deprotonation.
- Specific esters are functionalized with an α-hydroxyl group in the Chan rearrangement.
- Esters are converted to isocyanates through intermediate hydroxamic acids in the Lossen rearrangement.
- Esters with β-hydrogen atoms can be converted to alkenes in ester pyrolysis.
[edit] External links
- An introduction to esters
- Molecule of the month: Ethyl acetate and other esters
- Making an Ester A simple guide to naming and making esters, as well as the chemistry behind it.
[edit] References
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