6.1 - Aromatic compounds and carbonyls

Question 1

Describe the Kekulé model that the German chemist, Friedrich August proposed?

Answer 1

> That benzene was a planar ring of carbon atoms with alternating single and double bonds between them.
There would be 3 bonds that have the length of a C=C bond and 3 bonds with the length of a C-C bond.

Question 2

What are 3 pieces of evidence that disapprove the Kekulé structure?

Answer 2

> Benzene is resistant to addition reactions whereas the Kekulé structure is very reactive due to the C=C bonds such as in alkenes.
Enthalpy of hydrogenation of benzene shows that benzene is much more stable than predicted.
All 6 carbon bonds in benzene are the same length.

Question 3

Describe the bonding and structure of the delocalised model of benzene that replaced the Kekulé model?

Answer 3

In the structure, each of the 6 carbon atoms donates 1 electron from its p-orbitals which form π bonds and a ring of delocalised electrons above and below the plane of the molecule. The p-orbitals of all 6 carbon atoms overlap to create a π system. All bonds in the ring are identical so have the same length.

Question 4

Describe how the enthalpy changes of hydrogenation gives more evidence to the delocalised model?

Answer 4

The experimental enthalpy of hydrogenation of benzene is -208kj mol-1 which is far less exothermic than expected. This means that more energy must have been put in to break the bonds in benzene than the bonds in the Kekulé structure. This indicates that benzene is more stable which is thought to be due to the delocalised ring of electrons.

Question 5

What was the suspected enthalpy change of hydrogenation for benzene and why?

Answer 5

Cyclohexene has one double bond and when it is hydrogenated it has an enthalpy change of -120kj mol-1. So it was thought since benzene has 3 double bonds in the Kekulé structure it would be (3 x -120) = -360kj mol-1.

Question 6

What is the difference between alkenes and benzene and what does it cause?

Answer 6

The π-system in benzene - the delocalised electron rings above and below the plane of carbon atoms spread out the negative charge and make the benzene ring very stable. It is unwilling to undergo addition reactions which would destroy the benzene ring, further evidence for the delocalised model.

Question 7

Describe the electrophilic substitution reactions of benzene?

Answer 7

A hydrogen atom is substituted by an electrophile.

1) Addition of the electrophile to form a positively charged intermediate.
2) A loss of H+ from the C atom attached to the electrophile, reforming the delocalised ring.

Question 8

Why do halogen carriers help make good electrophiles?

Answer 8

Using a catalyst of a halogen carrier will accept a lone pair of electrons from a halogen atom on an electrophile. As the lone pair is pulled away, the polarisation in the molecule increases and sometimes a carbocation forms, making the electrophile stronger.

Question 9

Give a few examples of halogen carriers?

Answer 9

Aluminium halides, iron halides and iron.

Question 10

How do halogen carriers help halogens substitute into the benzene ring?

Answer 10

The catalyst polarises the halogen, allowing one of the halogen atoms to act as an electrophile. During the reaction, a halogen atom is substituted in place of a H atom - this is called halogenation.

Question 11

How are Friedel-Crafts reactions that form C-C bonds in organic synthesis carried out?

Answer 11

By refluxing benzene with a halogen carrier and either a haloalkane or an acyl chloride.

Question 12

What happens in Friedel-Crafts acylation?

Answer 12

Substitutes an acyl group for an H atom on benzene.

Question 13

What forms when you warm benzene with conc. nitric acid and conc. sulfuric acid and why is the sulfuric acid important?

Answer 13

You get nitrobenzene.
Sulfuric acid is a catalyst - it helps make the nitronium ion NO2+, which is the electrophile. It’s then regenerated at the end of the reaction mechanism.

Question 14

What is the formula of phenol?

Answer 14

C6H5OH

Question 15

Why is phenol more reactive than benzene?

Answer 15

> One of the lone pairs of electrons in a p-orbital of the oxygen atom overlaps with the delocalised ring of electrons in the benzene ring.
The lone pair of electrons from the oxygen atom is partially delocalised into the π system.
This increases the electron density of the ring, making it mote likely to be attacked by electrophiles.
Therefore, the -OH group means that phenol is more likely to undergo electrophilic substitution.

Question 16

What type of groups direct substitutions towards carbons 2,4 and 6?

Answer 16

Electron donating groups.

Question 17

Give some examples of electron donating groups and why they are electron donating groups?

Answer 17

-OH and -NH2 for they have electrons in orbitals that overlap with the delocalised ring and increase its electron density.

Question 18

Why do electron donating groups direct substitutions to 2,4 and 6?

Answer 18

They increase the electron density at carbons 2,4 and 6 so electrophiles are most likely to react at these positions.

Question 19

Where do electron withdrawing groups direct substitution to?

Answer 19

Carbons 3 and 5.

Question 20

Give an example of a withdrawing group and why it is one?

Answer 20

-NO2, it doesn’t have any orbitals that can overlap with the delocalised ring and it’s electronegative, so it withdraws electron density from the ring.

Question 21

Why do electron withdrawing groups direct substitutions to 3 and 5 carbons?

Answer 21

It withdraws electron density at carbons 2,4 and 6 so the electrophiles are unlikely to react at these positions. This has the effect of directing electrophilic substitution to the 3 and 5 positions.

Question 22

What happens if you shake phenol with orange bromine water?

Answer 22

It will react, decolourising it for phenol is more reactive than benzene.
>The -OH group is electron donating so directs substitution to carbons 2,4 and 6. The product is called 2,4,6-tribromophenol.

Question 23

How can phenol be nitrated?

Answer 23

Phenol reacts with dilute nitric acid to give 2 isomers of nitrophenol, and water.

Question 24

Why is it much easier to nitrate phenol than benzene?

Answer 24

Due to the activating effect of the OH group.

Question 25

Will phenol undergo typical acid-base reactions?

Answer 25

Phenol is weakly acidic so reacts with bases and sodium to form salts.

Question 26

What happens when phenol reacts with sodium hydroxide solution?

Answer 26

At room temperature in a neutralisation reaction to form sodium phenoxide and water.

Question 27

What is one base that phenol doesn’t react with for it’s not a strong enough acid?

Answer 27

Sodium carbonate solution.

Question 28

What is the carbonyl functional group?

Answer 28

C=O

Question 29

How can you make aldehydes and carboxylic acids?

Answer 29

By oxidising primary alcohols with acidified potassium dichromate.

Question 30

How can you control how far the primary alcohol is oxidised?

Answer 30

> Gently heating a primary alcohol with acidified potassium dichromate in distillation apparatus will form an aldehyde.
If you reflux a primary alcohol with acidified potassium dichromate, then you’ll oxidise the aldehyde further and form a carboxylic acid.

Question 31

What is the difference in products when you reduce a ketone and an aldehyde?

Answer 31

> Reducing an aldehyde you form a primary alcohol.

>Reducing a ketone you form a secondary alcohol.

Question 32

What is the reducing agent you use for reducing aldehydes and ketones?

Answer 32

NaBH4

Question 33

What type of reaction is reduction?

Answer 33

Nucleophilic addition reaction - a nucleophile attacks the molecule, and an extra group is added to it.

Question 34

What happens when hydrogen cyanide reacts with carbonyls?

Answer 34

To produce hydroxynitriles.

Question 35

Describe what happens in the nucleophilic addition reaction where hydrogen cyanide reacts with carbonyls?

Answer 35

Hydrogen cyanide is a weak acid so it partially dissociates in water to form H+ and CN- ions.

1) The CN- ion attacks the slightly positive carbon atom and donates a pair of electrons to it. Both electrons from the double bond transfer to the oxygen.
2) H+ (from hydrogen cyanide or water) bonds to the oxygen to form a hydroxyl group (OH).

Question 36

What test can you use to tell if a substance is one of either an aldehyde or ketone?

Answer 36

> Brady’s reagent - it will react with carbonyl groups (just the C=O) to form a bright orange precipitate.

Question 37

How would you be able to identify the specific carbonyl compound?

Answer 37

Each different carbonyl compound produces a crystalline derivative with a different melting point. So measure the melting point of the crystals and compare it against the known melting points of the derivatives to identify it.

Question 38

What is a test you can use to distinguish between aldehydes and ketones?

Answer 38

Use tollen’s reagent.
>When heated together in a test tube the aldehyde is oxidised and the silver ions in the Tollen’s reagent are reduced to silver causing a silver mirror to form.

Question 39

What is the carboxyl functional group of carboxylic acids?

Answer 39

-COOH

Question 40

Why are carboxylic acids very soluble in water?

Answer 40

Carboxylic acids are polar molecules, since electrons are drawn towards the O atoms. Hydrogen bonds are able to form between the highly polarised H (delta +) atom and O (delta -) atoms on other molecules.

Question 41

What happens when carboxylic acids react with more reactive metals?

Answer 41

They form a salt and hydrogen gas in a redox reaction.

Question 42

What forms when a carboxylic acid reacts with carbonates?

Answer 42

Forms a salt, carbon dioxide and water.

Question 43

What happens when carboxylic acids are neutralised by other bases (alkalis/metal oxides)?

Answer 43

Form salts and water.

Question 44

What is the functional group and general formula of acyl chlorides?

Answer 44

-COCl

CnH2n-1OCl

Question 45

How are acyl chlorides made?

Answer 45

By reacting carboxylic acids with SOCl2 where the -OH group is replaced by -CI

Question 46

Acyl chlorides easily lose their chlorine. What happens when acyl chlorides react with water?

Answer 46

A vigorous reaction with cold water, producing a carboxylic acid and HCI

Question 47

What happens when acyl chlorides react with alcohols?

Answer 47

A vigorous reaction at room temperature, producing an ester and HCI

Question 48

What happens when acyl chlorides react with ammonia?

Answer 48

A violent reaction at room temperature producing a primary amide and HCI

Question 49

What happens when acyl chlorides react with amines (primary)?

Answer 49

A violent reaction at room temperature, producing a secondary amide and HCI

Question 50

Why is the formation of an ester with acyl chloride and an alcohol favored over producing an ester by reacting an alcohol and a carboxylic acid?

Answer 50

The irreversible reaction is much easier and faster.

Question 51

What type of reactions are those where Cl is substituted by an oxygen or nitrogen group and hydrogen chloride fumes are given off?

Answer 51

Nucleophilic addition-elimination reactions.

Question 52

Why do you use acyl chlorides to react with phenol rather than carboxylic acids to form esters?

Answer 52

Phenols react very slowly with carboxylic acids, so it’s faster to use an acyl chloride.

Question 53

What functional group do esters have?

Answer 53

-COO

Question 54

How do you name esters?

Answer 54

> Look at the alkyl group that came from the alcohol. This is the first bit of the ester’s name (e.g. ethyl).
Now look at the part that came from the carboxylic acid and give it an -oate end.
E.g. ethyl ethanoate

Question 55

What are three ways you can form esters?

Answer 55

> Alcohols and carboxylic acids.
Alcohols and acid anhydrides.
Alcohols and acyl chlorides.

Question 56

Describe how you can form an ester from an alcohol and carboxylic acid?

Answer 56

If you heat a carboxylic acid with an alcohol in the presence of an acid catalyst, you get an ester. Conc. sulfuric acid is usually used as the acid catalyst, It is an esterification reaction and is an example of a condensation reaction.

Question 57

How do you collect the product from an ester formed from an alcohol and carboxylic acid?

Answer 57

Since the reaction is reversible, so you need to separate out the product as it’s formed.
>For small esters you can warm the mixture and distil off the ester for it’s more volatile than the other compounds.
>Larger esters are harder to form so it’s best to heat them under reflux and use fractional distillation to separate the ester from the other compounds.

Question 58

What are the conditions needed when an alcohol and acid anhydride react to form an ester and what is the other product?

Answer 58

> Conditions - Acid anhydride is warmed with the alcohol. No catalyst needed.
An ester and a carboxylic acid which then can be separated by fractional distillation.

Question 59

How do you hydrolyse an ester using acid hydrolysis and what do you form?

Answer 59

You have to reflux the ester with a dilute acid, such as hydrochloric or sulfuric.
>Splits the ester into a carboxylic acid and an alcohol.

Question 60

How do you hydrolyse an ester using base hydrolysis and what do you form?

Answer 60

You have to reflux the ester with a dilute alkali, such as sodium hydroxide.
>You get a carboxylate salt and an alcohol.