Stereoisomerism: Geometrical & Optical
- Stereoisomers are compounds that have the same atoms connected to each other, however the atoms are differently arranged in space
- There are two types of stereoisomerism:
- Geometrical (cis/trans) isomerism
- Optical isomerism
Geometrical (cis/trans) isomerism
- Geometrical isomerism is seen in unsaturated (double bond containing) or ring compounds that have the same molecular formula and order of atoms (the atoms are connected similarly to each other) but different shapes
- Cis/trans nomenclature is used to distinguish between the isomers
- Cis isomers have functional groups on the same side of the double bond/carbon ring
- Trans isomers have functional groups on opposite sides of the double bond/carbon ring
Geometrical isomerism in unsaturated compounds
cis isomers have both functional groups above or both below the C=C bond. Trans isomers have one functional group above and one functional group below the C=C bond
Geometrical isomerism in cyclic compounds
The same principle of cis and trans applies to cyclic compounds, where cis means both functional groups above or below the ring structure and trans means one functional group above and the other below the ring structure
- This causes the compounds to have different chemical and physical properties
- For example, they may have different reaction rates for the same reaction (chemical property) or different melting/boiling points (physical property)
Optical isomerism
- Optical isomers arise when a carbon atom in a molecule is bonded to four different atoms or groups of atoms
- The carbon atom is ‘asymmetric’ as there is no plane of symmetric in the molecule and is also called the chiral centre of the molecule
- Just like the left hand cannot be superimposed on the right hand, enantiomers too are non-superimposable
- Enantiomers are mirror images of each other.
- The two different optical isomers are also called enantiomers
Optical isomers
Both molecules are made up of the same atoms which are bonded to each other identically, however the chiral centre (carbon with four different groups) gives rise to optical isomerism
- Optical isomers differ in their ability to rotate the plane of polarised light
- One enantiomer will rotate it clockwise and the other anticlockwise