When an oxygen atom forms a double bond to a carbon atom, a carbonyl functional group is obtained. The carbon atom of a carbonyl group is bonded to two other atoms in addition to the oxygen atom. A wide range of functional groups are produced by the presence of different atomic groupings on the carbon of the carbonyl group. Two of the most important are aldehydes and ketones. In a ketone, both atoms bonded to the carbonyl carbon are other carbon atoms, and, in an aldehyde, at least one atom on the carbonyl carbon is a hydrogen. Similar to the double bond of alkenes, the carbon-oxygen double bond is made up of a σ bond, whose electron pair lies between the bonded atoms, and a π bond, whose electron pair occupies space on both sides of the σ bond.
Many aldehydes and ketones have pleasant, fruity aromas, and these compounds are frequently responsible for the flavour and smell of fruits and vegetables. A 40 percent solution of formaldehyde in water is formalin, a liquid used for preserving biological specimens. Benzaldehyde is an aromatic aldehyde and imparts much of the aroma to cherries and almonds. Butanedione, a ketone with two carbonyl groups, is partially responsible for the odour of cheeses. Civetone, a large cyclic ketone, is secreted by the civet cat and is a key component of many expensive perfumes.
The carbonyl group has a wide variety of reaction pathways open to it. Because of its π bond, the carbonyl group undergoes addition reactions similar to those that occur with alkenes but with a few important differences. Whereas carbon-carbon double bonds are nonpolar, carbon-oxygen double bonds are polar. Species that add to a carbonyl group to form new σ bonds react in such a way that electrophilic (electron-seeking) groups attack the oxygen atom and nucleophilic groups (those seeking positively charged centres) attack the carbon atom. Furthermore, addition to a carbonyl group results in the breaking of a strong π bond. The energy relationships of carbonyl addition reactions are consequently very different from those of alkene addition reactions. Other reaction possibilities of carbonyl compounds depend on the nature of the atomic groupings, termed substituents, attached to the carbonyl carbon. When both substituents are unreactive alkane fragments, as in ketones, there are few reactions other than carbonyl additions. When one of the substituents is not an alkane fragment, different possibilities emerge. In aldehydes, the carbonyl carbon is bonded to a hydrogen atom, and reactions that involve this hydrogen atom distinguish the reactions of aldehydes from those of ketones.
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