– contain Hydroxyl group (OH) – suffix ol or hydroxy if a higher priority group is present- Diols contain two hydroxyl groups. * Geminal: 2 Hydroxyl groups on the same carbon* Vicinal: on adjacent carbons
In organic chemistry, a hydroxyl group (OH) is a functional group that consists of an oxygen atom bonded to a hydrogen atom, attached to a carbon atom in an organic molecule
In organic chemistry, a hydroxyl group (OH) is a functional group that consists of an oxygen atom bonded to a hydrogen atom, attached to a carbon atom in an organic molecule. This hydroxyl group is denoted as -OH.
The presence of a hydroxyl group in a compound has several implications. First, it can affect the chemical properties of the molecule, as it is a polar group, making the compound more likely to participate in hydrogen bonding and exhibit properties such as solubility in water.
When naming compounds with hydroxyl groups, the suffix “-ol” or “hydroxy” is used. For example, ethanol is named as such because it contains a hydroxyl group (-OH) attached to an ethyl group (-C2H5). Similarly, methanol is named because it contains a hydroxyl group (-OH) attached to a methyl group (-CH3). The priority of the hydroxyl group in the naming depends on the presence of any other functional groups in the molecule.
A diol is a compound that contains two hydroxyl groups. Diols can have different arrangements of the hydroxyl groups on the carbon skeleton. Two common arrangements are geminal and vicinal.
Geminal diols are also known as hydrates and have the two hydroxyl groups attached to the same carbon atom. An example of a geminal diol is ethane-1,2-diol, also known as ethylene glycol, which is commonly used in antifreeze. In this compound, both hydroxyl groups are bonded to the same carbon atom.
Vicinal diols, on the other hand, have the two hydroxyl groups attached to adjacent carbon atoms in the molecule. An example of a vicinal diol is butane-1,2-diol, also known as 1,2-butanediol, which is used in the production of plastics and solvents. In this compound, the hydroxyl groups are bonded to the two adjacent carbon atoms.
It is important to differentiate between geminal and vicinal diols because their chemical properties and reactivity can differ based on the arrangement of the hydroxyl groups. The position and arrangement of the hydroxyl groups in a diol can affect its stability, boiling point, acidity, and other properties.
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