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Optical Isomerism in Compounds without any Stereocentre | Organic Chemistry PDF Download

Optically activity in the absence of a chiral carbon/ sterecentre:

There are many cases where the Chirality is not because of the presence of one or more chiral centers, but it is because of the presence of other elements of Chirality.

Molecules belonging to the following category are chiral without chiral
(i) Allenes
(ii) Spiranes
(iii) Biphenyls
(iv) Cyclohexanes 

Optical activity due to a chiral axis:-

When four ligands attached to the central atom C are located on the corners of a regular tetrahedron, C is a chiral center of the molecule and is replaced by linear grouping of e.g. C—C or C=C=C.  The tetrahedron becomes elongated i.e. extended along the axis of grouping to produce a chiral axis XY. 

 Optical Isomerism in Compounds without any Stereocentre | Organic ChemistryOptical Isomerism in Compounds without any Stereocentre | Organic Chemistry

The minimum condit ion for Chiralit y of a elo ngated tetrahedron is that A should be different fro m B. i.e. pair of ligands at X end of the axis and pair of ligands at Y end of the axis are each constituted by different ligands.

Question for Optical Isomerism in Compounds without any Stereocentre
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Which of the following molecules are chiral without a chiral carbon?
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Stereochemistry of Allenes:-

When three or more adjacent carbon atoms in a molecule are bonded by double bonds, the compound is called cumulene or is said to have cumulative double bonds. Allene is the simplest cumulene

 Optical Isomerism in Compounds without any Stereocentre | Organic ChemistryOptical Isomerism in Compounds without any Stereocentre | Organic Chemistry

The spatial arrangement of the cumulative double bond in allene is such that its terminal methylene groups are

⊥ to  each other. This is easily understandable because the two terminal carbon atoms in allene are in Sp2 and the central carbon atom is in Sp hybrid state, thus central carbon forms two π bonds which are ⊥ to each other.
Thus allenes of the type:- abC=C=Cab (a≠b) are chiral.

  • In allenes if double bonds are even there are two ⊥ planes. If there is no plane of symmetry than molecule is chiral. If there is any plane of symmetry (then the molecule is achiral).
  • If cumulene has odd no of double bonds, then it is achiral due to mo lecular plane of symmetry or it shows geometrical isomerism. ·
  • A 2-fold rotational axis is present in allene when a=a and b=b
  • Since the replacement of a double bond in allene by a ring does not alter the basic geo metry of the molecule. ·
  • Compound where Sp2 carbon is replaced by nitrogen have also been obtained as enantiomers.

 Optical Isomerism in Compounds without any Stereocentre | Organic ChemistryOptical Isomerism in Compounds without any Stereocentre | Organic Chemistry

R-S configuration for allenes

 Optical Isomerism in Compounds without any Stereocentre | Organic Chemistry

Molecule is viewed from the point which is in plane. Substituents at this site are given priority 1 and 2 according to CIP Rule and thus other end is cited in the same way. Above shown figure shows how to assign configuration to allenes.
Problems:-

Optical Isomerism in Compounds without any Stereocentre | Organic ChemistryOptical Isomerism in Compounds without any Stereocentre | Organic Chemistry
Optical Isomerism in Compounds without any Stereocentre | Organic Chemistry

 Stereochemistry of Spirane :-If both the double bonds in allenes are replaced by a ring systems, the resulting molecules are known as spiranes or Spiro compounds.

Optical Isomerism in Compounds without any Stereocentre | Organic ChemistryOptical Isomerism in Compounds without any Stereocentre | Organic Chemistry

For Chirality X≠Y

If X=Y – plane of symmetry is present and molecule becomes achiral.

Optical Isomerism in Compounds without any Stereocentre | Organic ChemistryOptical Isomerism in Compounds without any Stereocentre | Organic ChemistryOptical Isomerism in Compounds without any Stereocentre | Organic Chemistry
Optical Isomerism in Compounds without any Stereocentre | Organic ChemistryOptical Isomerism in Compounds without any Stereocentre | Organic ChemistryOptical Isomerism in Compounds without any Stereocentre | Organic Chemistry
 

R-S configuration in case of spiranes:-

Optical Isomerism in Compounds without any Stereocentre | Organic Chemistry

Molecule is viewed from the point which is in plane. Substituents at this site are given priority 1 and 2 according to CIP Rule and thus other end is cited in the same way. Above shown figure shows how to assign configuration to spiranes.


Stereochemistry of biphenyls:-In the crystals, both benzene rings lie in the same plane. However, in solution and vapour phase the two rings are twisted with respect to each other by an angle 450 due to steric interactions between the 2,2’ and 6,6’ pairs of hydrogen’s. These interactions effects are further enhanced by ortho substituent’s larger than hydrogen so that

Optical Isomerism in Compounds without any Stereocentre | Organic Chemistry

The rotation about the bond linking the two phenyl rings doesn’t occur due to steric strain (hindrance) between the bulky ortho substituent’s.

Biphenyls show enantiomerism when following two conditions are satisfied

  • Each ring must be unsymmetrically subst ituted.

Optical Isomerism in Compounds without any Stereocentre | Organic ChemistryOptical Isomerism in Compounds without any Stereocentre | Organic Chemistry

  • Both rings must be substituted in ortho posit ions (minimum number of subst ituent’s should be two, one substituent in each ring) and the substituent must have a large size.

 

Optical Isomerism in Compounds without any Stereocentre | Organic ChemistryOptical Isomerism in Compounds without any Stereocentre | Organic ChemistryOptical Isomerism in Compounds without any Stereocentre | Organic Chemistry

Question for Optical Isomerism in Compounds without any Stereocentre
Try yourself:
Which of the following compounds is chiral?
View Solution
 

R-S configuration of biphenyls

Optical Isomerism in Compounds without any Stereocentre | Organic Chemistry
Optical Isomerism in Compounds without any Stereocentre | Organic Chemistry

Optical Isomerism in Compounds without any Stereocentre | Organic ChemistryOptical Isomerism in Compounds without any Stereocentre | Organic Chemistry

The document Optical Isomerism in Compounds without any Stereocentre | Organic Chemistry is a part of the Chemistry Course Organic Chemistry.
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FAQs on Optical Isomerism in Compounds without any Stereocentre - Organic Chemistry

1. What is optical isomerism in compounds without any stereocentre?
Ans. Optical isomerism is a type of stereoisomerism that arises when two molecules have the same molecular formula and the same bond connectivity but differ in the spatial arrangement of their atoms. In compounds without any stereocentre, optical isomerism arises due to the presence of a chiral environment, such as a crystal lattice or a surface. This phenomenon is also known as "pseudochirality" or "axial chirality."
2. How can compounds without any stereocentre exhibit optical isomerism?
Ans. Compounds without any stereocentre can exhibit optical isomerism if they possess a chiral axis, plane, or environment. A chiral axis is a line along which the molecule can be rotated to generate a non-superimposable mirror image. A chiral plane is a plane of symmetry that divides the molecule into two halves that are mirror images of each other. A chiral environment is a three-dimensional space that has a non-superimposable mirror image.
3. What are some examples of compounds without any stereocentre that exhibit optical isomerism?
Ans. Some examples of compounds without any stereocentre that exhibit optical isomerism include biphenyl, allenes, and spiranes. Biphenyl has a chiral axis that runs through the center of the molecule, while allenes have a chiral axis that runs along the carbon-carbon double bond. Spiranes have a chiral environment that arises from the three-dimensional arrangement of their atoms.
4. What is the significance of optical isomerism in compounds without any stereocentre?
Ans. Optical isomerism in compounds without any stereocentre is significant because it expands our understanding of the principles of stereochemistry and the various ways in which molecules can exhibit chirality. It also has practical applications in fields such as materials science, where chiral molecules are used to create advanced materials with unique properties.
5. How is optical isomerism in compounds without any stereocentre different from that in compounds with stereocentres?
Ans. Optical isomerism in compounds without any stereocentre is different from that in compounds with stereocentres because it arises from a different type of chirality. In compounds with stereocentres, chirality arises from the presence of four different substituents around a central carbon atom. In contrast, in compounds without any stereocentre, chirality arises from the three-dimensional arrangement of atoms around a chiral axis, plane, or environment.
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