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Pericyclic Reactions in Details (Part - 2) | Organic Chemistry PDF Download

Endo-principle. The dienophile can undergo reaction via two different orientations with respect to the plane of the diene (endo or exo). Maximum overlap of the n-orbitals of the diene and dienophile favors formation of the endo-adduct (secondary orbital overlap between the dienophile's activating substituent and the diene).

exo-Transition state (–CO2Me away from π-system of diene)


Pericyclic Reactions in Details (Part - 2) | Organic Chemistry

endo-Transition state (–CO2Me toward π-systenm diene)

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry

Note that the endo-product has the electron-withdrawing group cis to the (E, E)- substituents of the diene. Only one mode of stacking of the reagents is shown, with the diene above the dienophile. The other possibility is with the diene below the dienophile, leading to the enantiomer.

 In general, endo-selectivity is determined by a balance of electronic and steric effects. The endoselectivity may be improved by using Lewis acid catalysis to lower the temperature required for cycloaddition, as shown below.

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry


The diene will approach the dienophile from the face opposite a bulky substituent, and a dienophile will approach the less hindered face of the diene.

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry


6. Retro Diels-Alder reactions: Diels-Alder reactions are of course, reversible and the pathway followed for the reverse reaction can sometimes be as telling as the pathway for the forward reaction. The direction in which any pericyclic reaction takes place is determined by thermodynamics, with cycloadditions, like the diels-Alder reaction, usually taking place to form a ring because two π-bonds on the left are replaced by two σ-bonds on the right. A Diels-Alder reaction can be made to take place in reverse when the products do not react with each other rapidly.

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry


7. Intramolecular Cycloadditions

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry


As with intermolecular D-A reactions, the diastereoselectivity of intrainolecular cycloadditions can be improved by the addition of Lewis acids.


Pericyclic Reactions in Details (Part - 2) | Organic Chemistry


8. 1, 3-Dipolar Cycloadditions

1, 3-Dipoles react with alkenes or alkynes, or with heteroatom-containing double and triple bond like carbonyl groups or nitriles, to form heterocyclic rings. The kind of dipoles that feature in 1, 3-dipolar cycloadditions are isoelectronic with an allyl anion, having a conjugated system of three p-orbital on three atoms, X, Y and Z, and four electrons in the conjugated system. The range of possible structures is large; X, Y and Z are commonly almost any combination of C, N, O and S, with a double bond. Likewise, the dipolarophiles, analogous to dienophiles, have a double or triple bond between any pair A and B of the same common elements.

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry


Below are shown the core structures of the most important 1, 3-dipoles, and what they are all called. As with dienes, they can have electron-donating or withdrawing substituents attached at any of the atoms with a hydrogen atom in the core structure, and these modify the reactivity and selectivity that the dipoles show for different dipolarophiles. Some of the dipoles are stable compounds like ozone and diazomethane, or, suitably substituted, like azides, nutrones, and nitrile oxides. Other like the ylids mines, and carbonyl oxides are reactive intermediates that have to be made in situ.


Pericyclic Reactions in Details (Part - 2) | Organic Chemistry

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry

Azide Cycloadditions

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry


Nitrile Ylide Cycloadditions

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry


Diazoalkane Cycloadditions

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry


Nitrile Oxide Cycloadditions

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry


Carbonyl Ylide Cycloadditions

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry


Ozonolysis: The Prototypical Case

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry


Reaction Stereospecificity with dipolarophile

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry

Some good examples:

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry


Pericyclic Reactions in Details (Part - 2) | Organic Chemistry


Pericyclic Reactions in Details (Part - 2) | Organic Chemistry


3. CHELETROPIC REACTION

  • A special group of cycloaddition/cycloreversion reactions.
  • Two bonds are formed or broken at a single atom.
  • The nomenclature for cheletropic reactions is the same as for cycloadditions.

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry


Sulfolene dioxide

Sulfolene dioxide is subject to α-lithiation and alkylation, and this reaction has been used to introduce the ring into more complex molecules.

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry

Diazene

Concerted cheletropic elimination is the reaction of 3-pyrroline with N-nitrohydroxylamine gives rise to the diazene 21, which then undergoes elimination of nitrogen.

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry


CO elimination

Elimination of CO from bicyclo[2.2.1]heptadien-7-ones is very facile – almost spontaneous!

Pericyclic Reactions in Details (Part - 2) | Organic Chemistry

The document Pericyclic Reactions in Details (Part - 2) | Organic Chemistry is a part of the Chemistry Course Organic Chemistry.
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FAQs on Pericyclic Reactions in Details (Part - 2) - Organic Chemistry

1. What are pericyclic reactions?
Pericyclic reactions are a type of organic chemical reaction that involve the rearrangement of electrons within a cyclic system. These reactions occur without the formation or breaking of any bonds and proceed through a concerted mechanism.
2. What are the different types of pericyclic reactions?
There are three main types of pericyclic reactions: cycloaddition reactions, electrocyclic reactions, and sigmatropic rearrangements. Cycloaddition reactions involve the formation of a new cyclic compound by the combination of two or more reactants. Electrocyclic reactions involve the rearrangement of a cyclic compound through the breaking and formation of π bonds. Sigmatropic rearrangements involve the migration of a σ bond within a cyclic system.
3. How do pericyclic reactions differ from other types of reactions?
Pericyclic reactions differ from other types of reactions, such as substitution or elimination reactions, in several ways. Unlike these reactions, pericyclic reactions do not involve the formation or breaking of any bonds. They also occur in a single step, known as a concerted mechanism, without the intermediates or transition states typically observed in other reactions.
4. What is the significance of pericyclic reactions in organic chemistry?
Pericyclic reactions play a crucial role in organic chemistry as they provide a powerful tool for the synthesis of complex molecules. Their concerted mechanism allows for the efficient formation of multiple bonds and stereospecific transformations. Additionally, pericyclic reactions are often used in the synthesis of natural products, pharmaceuticals, and materials.
5. Can you provide an example of a pericyclic reaction?
One example of a pericyclic reaction is the Diels-Alder reaction. In this reaction, a conjugated diene and a dienophile combine to form a cyclic compound known as a cycloadduct. The Diels-Alder reaction is widely used in organic synthesis to construct complex ring systems and has applications in the preparation of drugs, fragrances, and polymers.
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