CbD - Reactions of aromatic compounds

Question 1

What reactions do arenes undergo?

Answer 1

Electrophilic substitution reactions.

Question 2

What electrophilic substitution reactions does benzene undergo?

Answer 2

• Bromination
• Chlorination
• Nitration
• Sulfonation

Friedel-craft reactions:

• Alkylation
• Acylation

Question 3

Bromination

Answer 3

Benzene reacts with liquid bromine in the presence of a catalyst, such as iron filings or iron(III) bromide.

Heat is necessary.

The bromine is decolourised and fumes of HBr are given off.

Question 4

What catalyst is usually used in bromination and why?

Answer 4

Iron filings or iron(III) bromide - to form the Br+ ion.

Question 5

What conditions are needed for bromination?

Answer 5

Br2 is needed (usually from FeBr3 or formed in situ from Fe).

Reflux.

Question 6

Chlorination

Answer 6

Benzene reacts in the same way as in bromination but in the presence of an aluminium chloride catalyst.

Anhydrous conditions.

Question 7

What catalyst is usually used in chlorination and why?

Answer 7

Aluminium chloride (AlCl3) as it is used as the halogen carrier.

Question 8

What conditions are needed for chlorination?

Answer 8

Cl2 from AlCl3

Question 9

What is the role of the iron catalyst in bromination?

Answer 9

Br+ is generated from the action of the catalyst.

• Iron reacts with bromine to form iron(III) bromide, FeBr3.
  2Fe + 3Br2 –> 2FeBr3
• The FeBr3 then interacts with a neighbouring bromine molecule - a Br- ion is removed from it to form the Br+ electrophile.
• Br+ then bonds to a carbon atom in the benzene ring and an H+ ion is lost from the ring.
• The H+ reacts with the FeBr4^- to produce HBr and regenerate the FeBr3 catalyst.
  H+ + FeBr4^- –> HBr + FeBr3

Question 10

What are halogen carriers?

Answer 10

Substances that are able to remove halogen atoms from molecules.

Question 11

Substances that are able to remove halogen atoms from molecules are known as what?

Answer 11

Halogen carriers.

Question 12

What equation shows how AlCl3 is a halogen carrier in chlorination?

Answer 12

Cl2 + AlCl3 –> AlCl4^- + Cl+

Question 13

At what temperature does chlorination occur and why?

Answer 13

Room temperature because of the combination of reactive chlorine and the powerful halogen carrier aluminium chloride.

AlCl3 reacts violently with water, so the reaction must be carried out under anhydrous conditions.

Question 14

What do halogen carriers do?

Answer 14

Polarise halogen molecules such as Br2 or Cl2

The positively charged end of the halogen molecule then acts as an electrophile and reacts with the benzene ring in the usual electrophilic substitution reaction.

Question 15

What does an electrophile need to be/have to be able to attack the stable benzene ring?

Answer 15

A pretty strong positive charge - only positive ions or strongly polar compounds will do this.

Question 16

How do halogen carriers make good electrophiles?

Answer 16

Most compounds aren’t polarised enough to be good electrophiles but some can be made into stronger electrophiles using a catalyst called a halogen carrier.

A halogen carrier accepts a lone pair of electrons from a polar molecule containing a halogen - the electrophile. As the lone pair of electrons is pulled away, the polarisation in the electrophile increases and sometimes a carbocation forms. This makes the electrophile loads stronger.

Question 17

Examples of halogen carriers

Answer 17

Aluminium halides, iron halides and iron.

Question 18

What is a carbocation?

Answer 18

An organic ion with a positively charged carbon atom.

Question 19

What is the importance of halogenated benzene derivatives?

Answer 19

Benzene rings with halogens attached have been found to be important intermediates in synthetic routes.

The carbon atom attached to the halogen can be made to attack other carbon atoms and this ability to form carbon-carbon bonds is crucial if chemists wish to make large complex molecules from simpler starting materials.

Question 20

Nitration

Answer 20

When you warm benzene with concentrated nitric and sulfuric acid, you get nitrobenzene.

Sulfuric acid is a catalyst - it helps to make the nitronium ion, NO2^+, which is the electrophile.

Need to keep temperature below 55 degrees.

Question 21

Conditions required for nitration

Answer 21

HNO3

c. H2SO4, below 55 degrees.

Question 22

Why is sulfuric acid needed in nitration?

Answer 22

It is a catalyst - helps in the formation of the nitronium ion, NO2^+, which is the electrophile.

Question 23

What catalyst is needed in nitration and why?

Answer 23

Sulfuric acid, H2SO4.

Helps in the formation of the nitronium ion, NO2^+, which is the electrophile.

Question 24

Electrophile in bromination

Answer 24

Br+

Question 25

Electrophile in chlorination

Answer 25

Cl+

Question 26

Electrophile in nitration

Answer 26

NO2^+

Question 27

Electrophile in sulfonation

Answer 27

SO3

Question 28

Sulfonation

Answer 28

When you boil benzene under reflux with concentrated sulfuric acid for several hours, or, warm benzene to 40 degrees with fuming sulfuric acid for half an hour, you make benzenesulfonic acid.

Need sulfur trioxide, SO3 as the electrophile.

Question 29

Product of nitration

Answer 29

nitrobenzene

Question 30

Product of sulfonation

Answer 30

benzenesulfonic acid

Question 31

Conditions needed for sulfonation

Answer 31

c. H2SO4 as it contains SO3

Reflux

Question 32

Why is sulfuric acid needed in sulfonation?

Answer 32

As it contains SO3 because it breaks up like this:

H2SO4 –> H2O + SO3

Question 33

Why does fuming sulfuric acid warmed to 40 degrees with benzene produce benzenesulfonic acid?

Answer 33

Fuming sulfuric acid is basically just a lot of SO3 molecules dissolved in sulfuric acid.

Question 34

Why is the reaction of warming benzene to 40 degrees with fuming sulfuric acid for half an hour ‘better’ than boiling benzene under reflux with concentrated sulfuric acid for several hours to produce benzenesulfonic acid?

Answer 34

Fuming sulfuric acid is basically just a lot of SO3 molecules dissolved in sulfuric acid. It is much richer in SO3 than c. H2SO4 which is why the reaction is quicker and needs less heating.

Question 35

Example of a carbon-carbon bond forming reaction

Answer 35

Friedel-Crafts reaction

Question 36

What type of reaction is it when AlCL3/FeCl3 are used as halogen carrier catalysts to help polarise organic molecules that contain halogens and cause them to substitute in a benzene ring?

Answer 36

Friedel-Crafts reaction

Question 37

Alkylation

Answer 37

Benzene is heated under reflux with a chloroalkane and anhydrous aluminium chloride to form an alkylbenzene.

Question 38

How can alkyl groups be substituted for H atoms on benzene rings?

Answer 38

By refluxing a chloroalkane and benzene with a halogen carrier such as AlCl3.

Question 39

What does reflux mean?

Answer 39

Boiling reactants in a flask fitted with a condenser to stop them boiling away.

Question 40

Conditions for alkylation

Answer 40

Chloroalkane

Anhydrous AlCl3

Reflux

Question 41

Electrophile in alkylation

Answer 41

Carbocation formed from the chloroalkane and AlCl3

Question 42

Why do compounds such as AlCl3 and FeBr3 help benzene to react with halogens?

Answer 42

AlCL3/FeCl3 are used as halogen carrier catalysts to help polarise organic molecules that contain halogens and cause them to substitute in a benzene ring.

They are friedel-crafts catalysts.

Question 43

What part attaches to the benzene ring in alkylation and acylation?

Answer 43

The chlorine end.

The chlorine is removed then the chain/molecule is added.

Question 44

Conditions for acylation

Answer 44

Acyl chloride

Anhydrous AlCl3

Reflux

Question 45

Electrophile in acylation

Answer 45

Acylium ion formed from the acyl chloride and AlCl3

Question 46

Acylation

Answer 46

When benzene is treated with an acyl chloride (or acid anhydride) and aluminium chloride under anhydrous conditions acylation occurs as an acyl group becomes attached to the benzene ring.

Question 47

What does acylation produce?

Answer 47

Phenylketones (+ HCl).

Question 48

What is the importance of Friedel-Crafts alkylations and acylations?

Answer 48

They are particularly useful to synthetic chemists, because they provide a way of adding carbon atoms to the benzene ring and building up side chains.

Question 49

What is the importance of nitration reactions?

Answer 49

Inserting nitro groups into a benzene ring that is part of a chromophore will modify the properties of the chromophore. It will change the wavelength of light that it absorbs and the molecule will have a different colour.

Question 50

What is the importance of sulfonation reactions?

Answer 50

Because the sulfonic acid group is able to form ionic salts, sulfonation provides a way of forming more soluble derivatives of aromatic compounds. Dyes are often made more soluble by adding sulfonic acid groups.