10. Aromatic Chemistry

Question 1

What structure are arenes based on?

Answer 1

A benzene ring structure

Question 2

How many carbons and hydrogens does benzene contain?

Answer 2

6 of each

Question 3

How was the bonding in a benzene ring originally thought to be?

Answer 3

A ring of six carbon atoms containing alternate single and double bonds

Question 4

What is the IUPAC name of a cyclic structure with alternate single and double bonds?

Answer 4

Cyclohexa - 1, 3, 5 - triene

Question 5

What is the molecular formula of cyclohexa - 1, 3, 5 - triene?

Answer 5

C6H6

Question 6

What is the Kekule structure?

Answer 6

What the structure of benzene was originally thought to be; six carbon atoms with alternate single and double bonds

Question 7

Do double and single bonds have the same length?

Answer 7

No

Question 8

Why are double bonds shorter than single bonds?

Answer 8

The extra overlap of the π orbitals brings the atoms closer together and the bond is shorter

Question 9

What was the evidence that benzene could not have the Kekule structure?

Answer 9

Analysis of benzene shows all bonds have the same length; but single and double bonds are different lengths

Question 10

What are the length of the bonds in benzene?

Answer 10

0.142 nm - intermediate between single and double

Question 11

What is the length of a C-C bond?

Answer 11

0.154 nm

Question 12

What is the length of a C=C bond?

Answer 12

0.134 nm

Question 13

What was the alternate suggestion to the Kekule structure for benzene?

Answer 13

Contained delocalised electrons in six overlapping p orbitals at right angles to the plane of atoms

Question 14

Describe the structure of benzene

Answer 14

• delocalised electrons in six overlapping p orbitals at right angles to the plane of atoms
• p-orbitals overlap sideways with both neighbours and the six electrons are delocalised above and below the ring

Question 15

How can the delocalised electrons in benzene be represented?

Answer 15

As a circle within the hexagonal ring

Question 16

What effect do the p-electrons in benzene have on stability?

Answer 16

They have a stabilising effect, meaning it is hard for an addition reaction to take place

Question 17

What are arenes?

Answer 17

Hydrocarbons based on benzene

Question 18

Why is it hard for an addition reaction to take place with benzene?

Answer 18

The 6 delocalised p electrons have a stabilising effect

Question 19

What shape is benzene?

Answer 19

Planar

Question 20

What are all the bond angles in benzene?

Answer 20

120°

Question 21

What happens when benzene is added to water?

Answer 21

It doesn’t decolourise

Question 22

Why doesn’t benzene decolourise when added to water?

Answer 22

There are no double bonds so it is difficult for an addition reaction to take place

Question 23

What is more stable: benzene or cyclohexa - 1, 3, 5 - triene?

Answer 23

Benzene due to delocalised electrons

Question 24

What are the two ways aromatic compounds can be named?

Answer 24

• based on benzene

* based on phenyl

Question 25

What do aromatic compounds all contain?

Answer 25

Benzene

Question 26

What does it mean, if aromatic compounds are named based on benzene?

Answer 26

The benzene ring is classed as the main functional group

Question 27

How are aromatic compounds named if they are named based on benzene?

Answer 27

With the suffix -benzene

Question 28

How would a benzene ring with one chlorine atom instead of a hydrogen be named?

Answer 28

Chlorobenzene (C6H5Cl)

Question 29

How would a benzene ring with one NO2 group instead of a hydrogen be named?

Answer 29

Nitrobenzene (C6H5NO2)

Question 30

How would a benzene ring with one CH3 group instead of a hydrogen be named?

Answer 30

Methylbenzene (C6H5CH3)

Question 31

How would a benzene ring with one CH2Cl group instead of a hydrogen be named?

Answer 31

Chloromethylbenzene (C6H5CH2Cl)

Question 32

What does it mean, if aromatic compounds are named based on phenyl?

Answer 32

When the benzene is not the main functional group

Question 33

How are aromatic compounds named if they are named based on phenyl?

Answer 33

The benzene is named as a prefix using -phenyl, with the suffix coming from the other functional group

Question 34

How would a benzene ring with one NH2 group instead of a hydrogen be named?

Answer 34

Phenylamine (C6H5NH2)

Question 35

How would a benzene ring with one COCH3 group instead of a hydrogen be named?

Answer 35

Phenylethanone (C6H5COCH3)

Question 36

How would a benzene ring with one CH=CH2 group instead of a hydrogen be named?

Answer 36

Phenylethene (C6H5CH2CH2)

Question 37

What are common examples of aromatic compounds which do not use benzyl or phenyl in full in the name?

Answer 37

• benzoic acid (C6H5COOH)

* phenol (C6H5OH)

Question 38

Structural formula for benzoic acid?

Answer 38

C6H5COOH

Question 39

Structural formula for phenol?

Answer 39

C6H5OH

Question 40

How are you supposed to know when you should name a compound based on phenyl or benzene?

Answer 40

There is no easy way to know - just learn common examples and use these to base the name of other molecules on

Question 41

When should numbers be used in the names of aromatic compounds?

Answer 41

When there is more than one functional group bonded to the benzene ring

Question 42

How can the unexpected stability of benzene be illustrated?

Answer 42

By considering thermochemical data from hydrogenation of benzene in comparison to that of cyclohexene

Question 43

How does the enthalpy change for cyclohexene and benzene show that benzene has delocalised electrons?

Answer 43

• cyclohexene = - 120 kJ mol-1 (breaking 1 double bond in process)
• enthalpy change for benzene should be 3 x -120 = -360 kJmol-1 (but it is only -208kJmol-1)
• benzene reaction is less exothermic than expected illustrating benzene is more stable than that of the Kekule structure

Question 44

What type of reactions does benzene not favour?

Answer 44

Those which would involve breaking up the delocalised system - so benzene won’t readily undergo addition reactions

Question 45

What do the delocalised electrons in benzene constitute?

Answer 45

An electron rich area

Question 46

What does it mean, that delocalised electrons constitute an electron rich area in benzene?

Answer 46

They are susceptible to attack by electrophiles

Question 47

Why does benzene undergo electrophilic substitution?

Answer 47

The electron rich area of delocalised electrons makes them susceptible to attack by electrophiles

Question 48

What do the delocalised electrons prevent benzene reacting as?

Answer 48

An alkene

Question 49

Why is electrophilic addition unlikely to occur in benzene?

Answer 49

The energy required for the ring to break in an electrophilic addition reaction is too high

Question 50

What reactions do benzene undergo?

Answer 50

Electrophilic substitution

Question 51

What does benzene undergo, as opposed to electrophilic addition?

Answer 51

Electrophilic substitution

Question 52

Why does electrophilic substitution occur in benzene?

Answer 52

• presence of delocalised electrons means the benzene ring is electron rich
• therefore an electrophile that is able to accept an electron pair donated by the ring is the most likely type of reagent to react with benzene

Question 53

In electrophilic substitution of benzene, why is the positive intermediate species more stable than a normal cation?

Answer 53

Due to the delocalised electrons

Question 54

In electrophilic substitution of benzene, how is the stability of the ring restored?

Answer 54

A proton is eliminated

Question 55

What type of electrophile is needed for electrophilic substitution with benzene? Why is this?

Answer 55

A ‘powerful’ one (a polar molecule or induced dipole isn’t enough), in order to react with such a stable molecule

Question 56

Can polar molecules be electrophiles in the electrophilic substitution of benzene?

Answer 56

No - because benzene is too stable so the electrophile needs to be more ‘powerful’

Question 57

What generates the electrophile in the electrophilic substitution of benzene?

Answer 57

A catalyst

Question 58

What is nitration?

Answer 58

The electrophilic substitution of benzene where the electrophile is a nitronium ion

Question 59

What is the formula for a nitronium ion?

Answer 59

NO₂⁺

Question 60

In nitration, how is the nitronium ion generated?

Answer 60

By the reaction between nitric and sulphuric acid

Question 61

What is the process of generating nitronium ions?

Answer 61

1. Nitric acid (the weaker acid) acts as a base and accepts a proton

H₂SO₄ + HNO₃ → H₂NO₃⁺ + HSO₄⁻

2. Water is lost

H₂NO₃⁺ → H₂O + NO₂⁺

Question 62

What are the two equations and overall equation for how nitronium ions are formed?

Answer 62

H₂SO₄ + HNO₃ → H₂NO₃⁺ + HSO₄⁻

H₂NO₃⁺ → H₂O + NO₂⁺

overall: H₂SO₄ + HNO₃ → NO₂⁺ + HSO₄⁻ + H₂O

Question 63

What happens with benzene, once a nitronium ion is generated?

Answer 63

Electrophilic substitution takes place

Question 64

What is the overall equation for benzene and nitric acid?

Answer 64

C6H6 + HNO3 → C6H5NO2 + H2O

Question 65

What mechanism is nitration?

Answer 65

Electrophilic substitution

Question 66

What are the reagents for nitration?

Answer 66

Concentrated nitric acid and concentrated sulphuric acid

Question 67

What are the conditions for nitration?

Answer 67

Warm to 50°C

Question 68

In nitration, what must be ensured about the temperature?

Answer 68

That it doesn’t rise above 55°C

Question 69

Why in nitration is the temperature ‘warm to 50°C’?

Answer 69

Otherwise further substitution will occur

Question 70

What does nitration produce?

Answer 70

Compounds which can be turned into other molecules ie they are useful in the synthesis of other organic compounds

Question 71

What are the uses of nitration?

Answer 71

• synthesis of amines and dyes

* manufacture of explosives

Question 72

How is nitrobenzene used in the synthesis of amines and dyes?

Answer 72

It can be reduced to phenyl amine by treating it with tin and concentrated HCl and heating under reflux

Question 73

How can nitrobenzene be reduced to phenyl amine?

Answer 73

By treating it with tin and concentrated HCl and heating under reflux

Question 74

Why must nitrobenzene be heated under reflux to form phenylamine?

Answer 74

Otherwise it is impossible to introduce NH2 into a benzene ring

Question 75

Why should LiAlH₄ and NaBH₄ not be used in the reduction of nitrobenzene to phenyl amine?

Answer 75

Since they give other products

Question 76

Equation for the reduction of nitrobenzene to form phenyl amine?

Answer 76

C6H5NO2 + 6[H] → C6H5NH2 + 2H2O

Question 77

What can be used as a reducing agent, as opposed to tin and concentrated HCl, for the reduction of nitrobenzene to phenyl amine?

Answer 77

Hydrogen gas in the presence of a suitable catalyst

Question 78

What type of reaction is that of nitrobenzene to form phenyl amine?

Answer 78

Reduction

Question 79

What are phenyl amines used to manufacture?

Answer 79

Dyes

Question 80

What happens to nitro compounds when heated?

Answer 80

Decompose violently

Question 81

Why are nitro compounds used as explosives?

Answer 81

They decompose violently when heated

Question 82

What is the IUPAC name for TNT?

Answer 82

2, 4, 6 - trinitromethylbenzene

Question 83

How is TNT made?

Answer 83

By introducing 3 nitro groups into methyl benzene by reacting with concentrated nitric acid and sulphuric acids

Question 84

What are Friedel-Crafts acylation reactions?

Answer 84

Electrophilic substitution where a hydrogen atom on the benzene ring is substituted for an acylium ion

Question 85

What is an acylium ion?

Answer 85

R - C = O⁻

Question 86

In Friedel-Crafts acylation reactions, how is the acylium ion generated?

Answer 86

Using an acyl chloride and an anhydrous AlCl₃ catalyst

Question 87

What are the main steps in Friedel-Crafts acylation reactions?

Answer 87

• acylium ion generated
• RCO⁺ acts as electrophile that attacks benzene ring
• AlCl₃ is then regenerated

Question 88

What is the equation for the formation of an acylium ion using an acyl chloride and an anhydrous AlCl₃ catalyst?

Answer 88

R-COCl + AlCl₃ → R-CO⁺ + AlCl₄⁻

Question 89

Why is the formation of an acylium ion possible?

Answer 89

As the Al atom can accept a lone pair from the chloride atom in the acyl chloride forming a coordinate bond

Question 90

What is the equation for the regeneration of the AlCl₃ catalyst in the Friedel-Crafts acylation reactions?

Answer 90

AlCl₄⁻ + H⁺ → AlCl₃ + HCl

Question 91

What 3 reactions are covered in the aromatic chemistry topic?

Answer 91

1. nitration (benzene → nitrobenzene)
2. acylation (benzene → phenylketone)
3. reduction (nitrobenzene → phenyl amine)