Electrophilic Aromatic Substitution Reactions PDF

Summary

This document provides an overview of electrophilic aromatic substitution reactions in organic chemistry. It details various reactions like bromination, nitration, and sulfonation, discussing their mechanisms and conditions. The document explains how different substituents are introduced into aromatic rings.

Full Transcript

Electrophilic Aromatic Substitution Reactions
The most common reaction of aromatic compounds is
electrophilic aromatic substitution,
a process in which an electrophile (E) reacts with an
aromatic ring and substitutes for one of the hydrogens.

Many different substituents can be introduced onto the
aromatic ring by electrophilic substitution.
 To list some possibilities, an aromatic ring can be substituted by a halogen ( -
Cl, -Br, -I), a nitro group ( -NO2), a sulfonic acid group ( -SO3H), an alkyl group
(R), or an acyl group ( -COR).
Starting from only a few simple materials, it’s possible to prepare many
thousands of substituted aromatic compounds (Figure 5.2).
Mechanism of Electrophilic Aromatic Substitution

Chapter 17 3
 Bromination of Benzene
Bromine does not react with benzene at
room temperature.
For bromination of benzene to take place,
a catalyst such as FeBr3 is needed.
The catalyst makes the Br2 molecule more
electrophilic by reacting with it to give
FeBr4- and Br+.
The electrophilic Br+ then reacts with the
electron-rich (nucleophilic) benzene ring
to yield a carbocation intermediate that is
not aromatic. This carbocation is doubly
allylic and is a hybrid of three resonance
forms
Mechanism for the Bromination of Benzene: Step 1

+ -
Br Br FeBr3 Br Br FeBr3
(stronger electrophile than Br2)

Before the electrophilic aromatic substitution can take
place, the electrophile must be activated.
A strong Lewis acid catalyst, such as FeBr3, should be used.

Chapter 17 5
Mechanism for the Bromination of Benzene: Steps 2 and 3

Step 2: Electrophilic attack and formation of the sigma complex.
H H
H H H
H
Br Br FeBr3 Br
+ FeBr4-
H H H H
H H

Step 3: Loss of a proton to give the products.
H H
H FeBr4-
H H Br
Br
+ FeBr3 + HBr
H H H H
H H

Chapter 17 6
 Nitration of Benzene

NO2
HNO3
H2SO4 + H2O

Aromatic rings are nitrated by reaction with a mixture of concentrated nitric and sulfuric
acids.
This produces the electrophile of the reaction: nitronium ion (NO2+).
Sulfuric acid acts as a catalyst, allowing the reaction to be faster and at lower
temperatures.

Chapter 17 7
 Reduction of the Nitro Group

NO2 NH2
Zn, Sn, or Fe
aq. HCl

Aromatic nitration does not occur in nature; but it is particularly important in
the laboratory
because the nitro-substituted product can be reduced by reagents such as iron,
tin (Sn), or SnCl2 to yield an amino-substituted product, or arylamine, ArNH2.
This is the best method for adding an amino group to the ring in the industrial
synthesis of many dyes and pharmaceutical agents.

Chapter 17 8
 Sulfonation of Benzene

SO3H
H2SO4
+ SO3

Aromatic rings are sulfonated by reaction with fuming sulfuric acid (a 7% mixture of SO3
and H2SO4).
The reactive electrophile is HSO3 , and substitution occurs by the usual two-step
mechanism seen for bromination.
The —SO3H group is called a sulfonic acid.

Aromatic sulfonation is a key step in the synthesis of such compounds as the sulfa drug
family of antibiotics

Chapter 17 9
 Desulfonation Reaction

SO3H +
H
H , heat
+ H2O + H2SO4

Sulfonation is reversible.
The sulfonic acid group may be removed from an aromatic ring by
heating in dilute sulfuric acid.
In practice, steam is often used as a source of both water and heat
for desulfonation.
Chapter 17 10
 Nitration of Toluene

Toluene reacts 25 times faster than benzene.
The methyl group is an activator.
The product mix contains mostly ortho and para substituted
molecules.
Chapter 17 11
 The Friedel–Crafts Alkylation and Acylation
Reactions
One of the most useful electrophilic aromatic substitution
reactions is alkylation—the introduction of an alkyl group
onto the benzene ring.
Called the Friedel–Crafts alkylation reaction after its
discoverers,
the reaction is carried out by treating the aromatic
compound with an alkyl chloride, RCl, in the presence of
AlCl3to generate a carbocation electrophile, R+.
Aluminum chloride catalyzes the reaction by helping the
alkyl halide to dissociate in much the same way that
FeBr3catalyzes aromatic brominations by helping
Br2dissociate. Loss of H+ then completes the reaction
 Closely related to the Friedel–Crafts alkylation reaction is the Friedel–
Crafts acylation reaction.
When an aromatic compound is treated with a carboxylic acid
chloride (RCOCl) in the presence of AlCl3, an acyl (a-sil) group(R-C=O)
is introduced onto the ring.
For example, reaction of benzene with acetyl chloride yields the
ketone acetophenone.
Mechanism of the Friedel–Crafts Reaction
 Limitations of Friedel–Crafts
F-C reactions works only with benzene, activated benzene derivatives and
halobenzene. Reaction fails on aromatic rings that are strongly deactivated
(-NO2, -CN,-SO3H, or -COR.) Such aromatic rings are much less reactive than
benzene.

Like other carbocation reactions, the F-C alkylation is susceptible to carbocation
rearrangements.

The alkylbenzene product formed is more reactive than benzene, so multiple
alkylation (polyalkylation) occurs.
Chapter 17 15
 Clemmensen Reduction

The Clemmensen reduction is a way to convert acylbenzenes to
alkylbenzenes by treatment with aqueous HCl and amalgamated
zinc.

Chapter 17 16
 Substituent Effects in Electrophilic Aromatic
Substitution
Substituents affect both the reactivity of an aromatic ring and the
orientation of a reaction.
Substituents affect the reactivity of an aromatic ring
Some substituents activate a ring, making it more reactive than
benzene,
others deactivate a ring, making it less reactive than benzene.
In aromatic nitration, for instance, the presence of an OH substituent
makes the ring 1000 times more reactive than benzene,
while an NO2 substituent makes the ring more than 10 million times
less reactive
Activators Deactivators
 Substituents affect the orientation of a reaction
The three possible disubstituted products—ortho, meta, and para—
are usually not formed in equal amounts.

Instead, the nature of the substituent already present on the ring
determines the position of the second substitution.

An OH group directs further substitution toward the ortho and para
positions, for instance, while a CN directs further substitution
primarily toward the meta position.
 Effect of Multiple Substituents
Two or more substituents exert a combined effect on the reactivity of
an aromatic ring.
If the groups reinforce each other, the result is easy to predict.
For example in dimethylbenzene (Xylene), both methyl groups are
activating, and in nitrobenzoic acid, both substituents are
deactivating.
When the directing effects of two or more substituents conflict, it is
more difficult to predict where an E+ will react. In many cases a
mixture will result.
Activating groups are usually stronger directors than deactivating
groups.
 Effect of Multiple Substituents
OCH3 OCH3 OCH3
Br
Br2
FeBr3
O2N O2N O2N
Br

If directing effects oppose each other, the most
powerful activating group has the dominant
influence.
The directing effect of the two (or more) groups
may reinforce each other.
All activating groups are ortho
and para-directing,
and all deactivating groups other
than halogen are meta-directing.
The halogens are unique in being
deactivating but ortho- and para-
directing.
 Oxidation and Reduction of Aromatic compounds
CH2CH3 CO2H
KMnO4, NaOH
H2O, 100oC

(or Na2Cr2O7, H2SO4 , heat)

Despite its unsaturation, a benzene ring does not usually react
with strong oxidizing agents such as KMnO4
Alkyl groups attached to the aromatic ring are readily attacked by oxidizing
agents,
and are converted into carboxyl groups ( CO2H).
For example, Ethylbenzene is oxidized by KMnO4 to give benzoic acid.
 Nitration of Toluene

Toluene reacts 25 times faster than benzene.
The methyl group is an activator.
The product mix contains mostly ortho and para substituted
molecules.

Chapter 17 25
 Alkyl Group Stabilization

CH2CH3 CH2CH3 CH2CH3 CH2CH3
Br
Br2
FeBr3 + +
Br
Br
o-bromo m-bromo p-bromo
(38%) (< 1%) (62%)

Alkyl groups are activating substituents and ortho, para-
directors.
This effect is called the inductive effect because alkyl
groups can donate electron density to the ring through the
sigma bond, making them more active.
Chapter 17 26
Review on Electrophilic aromatic substitution
(EAS). What have we learned?
The aromatic ring acts as a nucleophile, and attacks an added electrophile E
An electron-deficient carbocation intermediate is formed (the rate-
determining step) which is then deprotonated to restore aromaticity
Electron-donating groups on the aromatic ring (such as OH, OCH3, and
alkyl) make the reaction faster, since they help to stabilize the electron-
poor carbocation intermediate
Electron withdrawing groups on the aromatic ring (such as NO2, SO3H and
CN makes the reaction slower)
Lewis acids can make electrophiles even more electron-poor (reactive),
increasing the reaction rate. For example FeBr3 / Br2 allows bromination to
occur at a useful rate on benzene, whereas Br2 by itself is slow).
 Nucleophilic Aromatic substitution
What is Nucleophilic Aromatic Substitution (NAS)?

How does NAS differ from Electrophilic Aromatic Substitution (EAS)?

Why does NAS tend to work best with electron-poor aromatics and
excellent nucleophiles?

Finally, how does it work?
 How does Nucleophilic Aromatic substitution differ from
Electrophilic Aromatic Substitution?
In Nucleophilic Aromatic substitution reaction,
The species that attacks the ring is a nucleophile, not an electrophile
The aromatic ring is electron-poor (electrophilic), not electron rich
(nucleophilic)
The “leaving group” is chlorine, not H+
The position where the nucleophile attacks is determined by where the
leaving group is, not by electronic and steric factors (i.e. no mix of ortho–
and para- products as with electrophilic aromatic substitution).
To be precise, the roles of the aromatic ring and attacking species are
reversed!
 In NAS,
electron withdrawing groups (EWG’s) dramatically increase the rate
of reaction, not decrease it. electrophilic aromatic substitution
operate, but in reverse.
Unlike in electrophilic aromatic substitution, there are no “ortho-
,para-” or “meta-” directors. The position of substitution is controlled
by the placement of the leaving group.