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Optical Isomerism is a property of Organic Compounds in which they have the same molecular and structural formula but they can't superimpose on each other. This is due to the different arrangement of carbon atoms in three-dimensional space. The structures exhibiting Optical isomerism are called Optical Isomers. Optical Isomerism is one of the most important concepts in Organic Chemistry and helps to understand various difficult reactions.
In this article, we will learn what is optical isomerism, its significance, types, examples and many more things.
Table of Content
Optical Isomerism is a kind of stereoisomerism which occurs when molecules are mirror images of one another but are not superimposable, despite sharing the same molecular and structural formulas. Because of their chiral centre, these molecules are also referred to as chiral molecules.
Optical Isomerism is defined as the property of organic compounds in which they have same molecular and structural formula but have non-superimposable images
Optical isomerism is significant in substances that rotate the plane of polarized light, and the amount of rotation is dependent on various factors such as the concentration of the substance in the solution, the path length of the sample tube, the wavelength of the incident light, and the nature of the substance itself.
One of the example of Optical isomerism is Butan-2-ol where the four carbons can be arranged in 3D space in two ways such as they are mirror image of each other and also non-superimposable.
An optical isomer, is a stereoisomer that is non-superimposable onto its own mirror image. They are also known as antipodes or optical antipodes.
One of the best examples of Optical Isomer is D and L Glyceraldehyde which is discussed below:
Glyceraldehyde exists in two isomerism forms that are mirror images of each other. These isomers are referred to as D and L Glyceraldehydes. This absolute configuration is defined because of the OH group present on the second carbon. When the OH group is present on the right side of the molecules, it is considered D-Glyceraldehyde; when it's present on the left side, it is considered L-Glyceraldehyde.
š Optical-Isomerism-Example
Chilarity is an important geometric property of a molecule's symmetry. On this basis, molecules are divided into two types which are:
Chiral molecules are molecules that have a non-superimposable mirror image. They are frequently identified as "right-handed" or "left-handed" based on some other criterion or their absolute configuration.
One or more chiral centres can be found in chiral molecules, which are nearly always tetrahedral (sp3-hybridized) carbons with four distinct substituents. The presence of an asymmetric carbon atom is often the feature that causes chirality in molecules. Chiral molecules are optically active, meaning they rotate polarized light.
Achiral molecules are superimposable with their mirror images, meaning they can be rotated to the same shape. These molecules have a plane of symmetry or a centre of symmetry. They may have chiral conformations but are not chiral due to their symmetry. They do not rotate plane-polarized light. Examples of achiral molecules include meso compounds, which have a stereocenter but are not chiral due to their symmetry.
Enantiomers are non-superimposable mirror images of each other, much like a person's right and left hands. They are often compared to hands because, without mirroring, one cannot be superimposed onto the other.
Enantiomers have distinct effects and interactions with other chiral molecules. They are distinguished by their ability to rotate plane-polarized light to equal but opposite angles, a property known as optical activity. When two enantiomers are present in equal proportions, they form a racemic mixture, which does not rotate polarized light because the optical activity of each enantiomer cancels out the other.
Enantiomers are chemically identical in every other respect, but they can have different effects on biological systems, making them significant in pharmaceuticals and other fields. The prefix "enantio-" designates the mirror-image relationship between enantiomers.
The two examples of Enantiomers are:
Here in the first molecule the OH group is present on the right side of the carbon atom hence it is called D-Lactic acid and on the hand, the second molecule has the OH group present on the second carbon therefore it is called as L-Lactic acid.
š Optical Isomerism in D-and-L-Lactic-Acid
Carvone can be synthesized from limonene and it was found to have a spearmint odor. It indicates that carvone is an optical isomer of limonene, and the synthesis of carvone from limonene demonstrates their relationship as enantiomers.
š Optical-Isomerism-Carvone and Limonene
Compounds showing optical isomers can be distinguished mainly into two types, which are:
There are three types of optical isomers in coordination compounds:
Octahedral complexes of type [M(xx)3]nĀ±, [M(xx)2AB]nĀ±, and [M(xx)2B2]nĀ± exhibit optical isomerism. For example, the optical isomers of [Co(en)3]3+ are shown below:
š Optical-Isomerism-in Coordination Compounds - Octahedral Complex
Cis-trans isomers exhibit optical isomerism when the whole molecule is asymmetric. For example, two geometrical isomers are possible in a coordination compound of type [Co(NH3)4(H20)2]3+. They are cis and trans. The cis isomer shows optically active isomerism among these two isomers because the whole molecule is asymmetric.
š Optical-Isomerism in Co(NH3)4(H2O)2
Square planar complexes of type [MX2L2] exhibit optical isomerism when the ligands L are different. For example, the complex [NiCl2(en)2] has two optical isomers.
Structural and optical isomers are two types of stereoisomers that differ in their arrangement in three-dimensional space. Here are the main differences between them:
Difference between Structural Isomers and Optical Isomers | |
|---|---|
Structural Isomers | Optical Isomers |
Also known as constitutional isomers | Also known as enantiomers or diastereomers |
These isomers have the same molecular formula but different structures, resulting in different arrangements of atoms. | These isomers have the same molecular formula and the same arrangement of atoms, but they differ in the placement of substituted groups around one or more atoms of the molecule. |
The chemical formula of a compound gives the chemical elements present in the compound and the number of atoms per chemical element. | Optical isomers rotate plane-polarized light in different directions and are related as non-superimposable mirror images. |
Examples of structural isomers include 1-butene and 2-butene, which have the same chemical formula but different arrangements of atoms. | Examples of optical isomers include glyceraldehyde, which has D and L isomers, and alpha and beta glucose. |
Learn,Geometric and Optical Isomerism
Optical isomerism in 2-chlorobutane results from a chiral centre at the second carbon atom, which has four groups attached. Due to this, 2-chlorobutane exhibits optical isomerism and has two enantiomers. The spatial arrangement of the four different groups (chlorine, hydrogen, and methyl) around the chiral atom is different in the two enantiomers. The structure of 2-chlorobutane and its mirror image cannot superimpose perfectly, making the compound optically active.
š Optical-Isomerism-in-2-Chlorobutane
In butan-2-ol, the second carbon atom has a hydroxy group, an ethyl group, a methyl group, and a hydrogen attached, making it an asymmetric carbon atom. This results in the molecule having two optical isomers, also known as enantiomers. To identify the optical isomers of butan-2-ol, consider the following skeletal formula:
In this formula, the second carbon atom (the one with the -OH attached) has four different groups around it, making it a chiral centre
Here are some of the critical applications:
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