Aldehyde vs. Ketones Terminal group
Aldehydes and ketones both belong to a class of organic compounds called carbonyl compounds, characterized by the presence of a carbonyl group (C=O)
Aldehydes and ketones both belong to a class of organic compounds called carbonyl compounds, characterized by the presence of a carbonyl group (C=O). The key difference between aldehydes and ketones lies in the position of the carbonyl group within the molecule.
In aldehydes, the carbonyl group is located at the end or terminal of the carbon chain. This means that there is at least one hydrogen atom attached to the carbon atom of the carbonyl group. The general formula for aldehydes is RCHO, where “R” represents an alkyl or aryl group.
On the other hand, ketones have the carbonyl group positioned within the carbon chain. In other words, both sides of the carbonyl group are attached to carbon atoms. The general formula for ketones is RCOR’, where “R” and “R'” represent alkyl or aryl groups. Ketones do not have a hydrogen atom directly attached to the carbonyl carbon.
This structural difference between aldehydes and ketones influences their physical properties and reactivity. Due to the presence of the terminal hydrogen atom, aldehydes can undergo oxidation to form carboxylic acids more easily compared to ketones. This is because the hydrogen atom in aldehydes is more readily available to react with an oxidizing agent. Ketones, lacking this terminal hydrogen atom, do not undergo oxidation easily.
Furthermore, the difference in structure affects the boiling points of aldehydes and ketones. Aldehydes generally have lower boiling points compared to ketones with similar molecular weights. This is because aldehydes have the ability to form intermolecular hydrogen bonds due to the presence of the terminal hydrogen atom. These hydrogen bonds result in stronger intermolecular forces, requiring more energy to break the bonds and elevate the boiling point.
In summary, the difference between aldehydes and ketones lies in the position of their carbonyl group within the molecule. Aldehydes have the carbonyl group at the terminal position, with a hydrogen atom directly attached to the carbonyl carbon. Ketones have the carbonyl group positioned within the carbon chain and lack a terminal hydrogen atom. These structural differences contribute to variations in their physical properties and reactivity.
More Answers:
Understanding Free Radical Halogenation: The Initiation, Propagation, and Termination of a Radical Chain Reaction in Organic ChemistryIntroduction to Aldehyde Nomenclature and Methanal: IUPAC and Common Name for the Simplest Aldehyde
How to Name Cyclic Aldehydes: A Guide to IUPAC Nomenclature