Elimination Reactions E1, E2, E1cb and Ei

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Elimination Reactions

Dr. H. Ghosh
Surendranath College, Kol-9
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E1, E2, E1cB and Ei (pyrolytic syn eliminations); formation of alkenes and alkynes;

mechanisms (with evidence), reactivity, regioselectivity (Saytzeff/Hofmann) and stereoselectivity;

Substitution Reactions Elimination Reactions

Elimination happens when the nucleophile attacks hydrogen instead of carbon

Strong Base favor Elimination
Bulky Nucleophile/Base favor Elimination
High Temperature favors Elimination

We know-

This equation says that a reaction in which ΔS is positive is more thermodynamically favorable at higher temperature.

Eliminations should therefore be favoured at high temperature

Keep in Mind----

Mechanism Classification

E1 Mechanism- Elimination Unimolecular

E1 describes an elimination reaction (E) in which the rate-determining step is unimolecular (1) and does not involve the base.

The leaving group leaves in this step, and the proton is removed in a separate second step

E2 Mechanism- Elimination Bimolecular

E2 describes an elimination (E) that has a bimolecular (2) rate-determining step that must involve the base. Loss of the leaving group is simultaneous with removal of the proton by the base

Bulky t-butoxide—ideal for promoting E2 as it’s both bulky and a strong base (pK_aH= 18).

Other Organic Base used in Elimination Reaction

These two bases are amidines—delocalization of one nitrogen’s lone pair on to the other, and the resulting stabilization of the protonated amidinium ion,

E1 can occur only with substrates that can ionize to give

relatively stable carbocations—tertiary, allylic or benzylic alkyl halides, for example.

E1-Elimination Reaction not possible here

The role of the leaving group

Since the leaving group is involved in the rate-determining step of both E1 and E2, in general, any good leaving group will lead to a fast elimination.
Stereoselectivity of E1 Reaction

E1 reactions can be regioselective
E2 eliminations have anti-periplanar transition states

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