Topic 18 : Organic III

Question 1

Describe the bonding between orbitals in benzene?

Answer 1

Orbital hybridisation produces 3 sp2 orbitals and 1 p orbital on each carbon, sigma bonding between 2 sp2 orbitals or between sp2 and s of hydrogens. Leftover p orbitals form a delocalised pi bond with the molecular orbital spread over the whole carbon ring.

Question 2

What does it mean if benzene is a resonance hybrid?

Answer 2

The structure is not actually resonating between the two forms of benzene (with the double and single bonds alternating), it has a single structure in which all the bonds are the same - between a single and double bond.

Question 3

How does the enthalpy of hydrogenation of benzene provide evidence for the structure?

Answer 3

The enthalpy of hydrogenation of benzene is lower than what would be expected ( roughly 3 x enthalpy of hydration of cyclohexene) which shows that the structure of benzene is not equivalent to cyclohexatriene.

Question 4

What roughly is the stabilising effect of the pi delocalisation?

Answer 4

~152kJ/mol

Question 5

How does the bond enthalpy of benzene compare to cyclohexatriene?

Answer 5

The bond enthalpy of benzene (worked out experimentally) is roughly 160kJ/mol more than the bond enthalpy of cyclohexatriene (worked out using average bond enthalpies). This suggests that more energy is needed to disrupt the bonding in benzene than in cyclohexatriene (this extra energy is referred to as the stabilising effect).

Question 6

How does IR data support the structure of benzene?

Answer 6

The IR spectrum from benzene is simpler because of greater symmetry in benzene than in cyclohexane.

Question 7

How does the delocalisation of pi-electrons in the benzene ring make it more stable than expected?

Answer 7

Delocalisation of the pi system means that the 6 electrons are evenly distributed through the benzene ring. This means that there are no areas of high electron density for electrophilic attack to occur.

Question 8

If the benzene ring is stable, why do arenes still undergo reactions such as halogenation and nitration?

Answer 8

Benzene is not electron rich enough to be attacked by a partially positive species, nevertheless species with a full positive charge will potentially attack the ring.

Question 9

What are the physical properties of benzene?

Answer 9

• Aromatic smell
• Non polar
• Van der waals between molecules are very strong - liquid at room temp
• Not soluble in water (immiscible)
• Carcinogenic

Question 10

Why does benzene undergo substitution reactions rather than addition reactions?

Answer 10

Benzene is thermodynamically very stable because of the delocalisation of the pi molecular orbital. Addition reactions would disrupt the delocalisation and hence reduce the stability of the ring. Substitution reactions only involve a temporary disruption of the delocalisation.

Question 11

Why is benzene resistant to attack by bromine (Br-Br)?

Answer 11

Pi electrons are delocalised so electron density between two carbon atoms is lower compared with alkenes. The electron density is insufficient to polarise a bromine molecule. Even distribution of the electrons in the ring makes the ring more stable and hence more energy is needed to disrupt the delocalised pi cloud of electrons.

A halogen carrier is needed to generate a more powerful electrophile, Br+. The charge is large enough to attract the pi electrons in benzene and disrupt the delocalised pi cloud of electrons.

Question 12

What are the conditions and reagents needed for the hydrogenation of cyclohexene?

Answer 12

Hydrogen gas, nickel catalyst, heat

Question 13

Why does the bond lengths in benzene suggest it is not equivalent to cyclohexatriene?

Answer 13

Electron diffraction measurements show that all the carbon-carbon bonds are of equal length (intermediate between C-C and C=C). In cyclohexatriene, the double bonds would be shorter than the C-C bonds.

Question 14

How many electrons are found in the pi bonding system above and below the plane of the atoms in the benzene molecule?

Answer 14

6

Question 15

Give 4 pieces of evidence benzene doesn’t have alternating single and double bonds.

Answer 15

1. Benzene doesn’t undergo electrophilic addition reactions like an alkene to produce disubstituted isomers
2. Electron diffraction measurements show that all the carbon-carbon bonds are of equal length/ intermediate between C-C and C=C
3. The enthalpy of hydrogenation of benzene is less exothermic than expected
4. The enthalpy of formation of benzene is less endothermic than expected

Question 16

Describe the combustion of benzene.

Answer 16

• Produces a characteristic sooty/smoky yellow flame in normal conditions (due to insufficient oxygen)
• requires a large volume of oxygen for complete combustion

Question 17

How does a halogen carrier allow substitution reactions of benzene with halogens to occur?

Answer 17

The halogen carries are covalent molecules and soluble in benzene.
The halogen carrier polarises the halogen molecule so that it behaves as an electrophile.

Br2 - FeBr3 or anhydrous AlBr3

Cl2 - FeCl3, anhydrous AlCl3

Question 18

What is the reaction for the formation of the electrophilie in halogenation reactions of benze?

Answer 18

Cl-Cl + FeCl3 -> [FeCl4]- + Cl+

Or with anhydrous AlCl3

Question 19

What is needed for the nitration of benzene?

Answer 19

Concentrated sulfuric acid
AND concentrated nitric acid
Reflux at 50 degrees C

Question 20

What is the overall equation for the nitration of benzene?

Answer 20

Benzene + nitric acid -> nitro-benzene + water
Concentration sulfuric acid cat. at 50 C

Question 21

Why is it important that nitration is performed at 50 degrees C?

Answer 21

Prevent more than one nitro group substituting onto the benzene.

Question 22

What is the equation for the generation of the electrophile for the nitration of benzene?

Answer 22

Nitric acid + sulfuric acid -> NO2+ + HSO4- + water

Concentrated nitric acid AND concentrated sulfuric acid

Question 23

What is the equation for the generation of the electrophile in alkylation and acylation reactions (Friedel-Crafts reactions)?

Answer 23

Alkylation: R-Cl + AlCl3 > R+ + [AlCl4]-
Acylation: R-OCl + AlCl3 -> +R=O + [AlCl4]-
heat needed for acylation

Question 24

What are examples of electron withdrawing groups?

Answer 24

Acyl, NO2, X, CN-

X - halogen

Question 25

What are examples of electron donating groups?

Answer 25

Alkyl, OH, NH2

Question 26

What is the effect of electron donating groups on reactions of the benzene ring?

Answer 26

Electrophilic substitutions occur faster than they would in benzene because there is more electron density in the ring.
Donating groups activate positions para and otho to themselves (carbons 2, 4, and 6)

Question 27

What is the effect of electron withdrawing groups on the reactions of the benzene ring?

Answer 27

Activates carbons meta to themselves (carbons 3,5).
Decreases the electron density in the ring so electophilic substitution reactions occur more slowly than they would in benzene itself.

Question 28

Physical properties of phenol

Answer 28

• Polar molecule
• Can form hydrogen bonds therefore higher boiling temperature
• Not very soluble in water below 66 degrees C
• Soluble in organic solvents
• Antiseptic smell
• Corrosive
• White solid at room temp

Question 29

What happens to the electrons on the oxygen in phenol?

Answer 29

Non-bonding electrons on the oxygen atom in the phenol group are drawn into the benzene ring.
The lone pair becomes part of the delocalisation increasing the electron density in the ring.
This makes the proton more acidic.

Question 30

Chemical properties of phenol

Answer 30

• As the oxygen adds electron density to the pi system, the pz electrons are drawn into the ring, the oxygen is less negative and the OH is therefore less effective in alcohol-type reactions
• Doesn’t react with oxidising agents, is seen as a tertiary alcohol
• Hydrogen atom is more acidic than in alcohols so phenol is more acidic than ethanol
• the benzene ring is more electrophilic
• Phenol reacts in aqueous conditions with no catalyst whereas benzene is anhydrous conditions with catalyst

Question 31

Acidic properties of phenol

Answer 31

• Phenol is stronger acid than ethanol but weaker than carboxylic acid.
• Phenol will not react with a carbonate to produce carbon dioxide gas
• Phenol does react with sodium to form hydrogen gas. The organic product formed is sodium phenoxide.

Question 32

Alcoholic properties of phenol

Answer 32

• Phenol does not react with carboxylic acids to form esters.
• The OH in phenol reacts slowly with PCl5 to give a poor yield of chlorobenzene

Question 33

The reaction of phenol with bromine

Answer 33

Bromine adds to carbon 2, 4, and 6.
Decolourises bromine water and white antiseptic smelling precipitate (2,4,6-tribomophenol) in a solution of HBr is formed immediately; effervescence and steamy fumes of HBr formed.

Question 34

phenols with ethanoic anhydride -> ?

Answer 34

Phenol + ethanoic anhydride -> phenylethanoate + ethanoic acid

Question 35

Reaction of salicylic acid + ethanoic anhydride

Answer 35

Salicylic acid (2-hydroxybenzoic acid) + ethanoic anhydride (acid catalyst) -> acetylsalicylic acid + ethanoic acid

Question 36

Butylamine + water

Answer 36

Butylammonium hydroxide [butyl-NH3]+[OH]-

forms alkaline solution

Question 37

Butylamine + ethanoic acid

Adjacent reaction happens with any other acid

Answer 37

butylammonium ethanoate [butyl-NH3]+[CH3COO]-

Forms a salt of ammonium ion conjugate base

Question 38

butylamine + ethanoyl chloride

Answer 38

butylNH2COCH3 + HCl
monosubstituted amide

Question 39

butylamine + chloroethane

works for any halogenoalkane

Answer 39

butyl-NH-ethyl + HCl
Disubstituted amine

Question 40

butylamine + cu(II)

Answer 40

[Cu(H2O)6]2+ + 6butylamine -> [Cu(butylamine)6]2+ +6H2O

forming complex ions

excess butylamine needed

Question 41

Put in order of increasing basicity:
ammonia, benzene-NH2, butylamine

Answer 41

benzene-NH2, ammonia, buylamine

Question 42

Why is benzene-NH2 a bad base?

Answer 42

Decreased electron density on N as lone pair drawn into delocalised pi system
Therefore harder to donate electron pair and harder to attract electrons

Question 43

Why is butylamine a better base than ammonia

Answer 43

• Increased electron density on N so easier to attract H+
• (because of) Positive inductive effect from electron donating alkyl chain
• Positive inductive effect also leads to stabilised positive charge on butylammonium
• Easier to donate electron pair due to repulsion

Question 44

State synthesis to prepare amines from halogenoalkanes

Answer 44

halogenoalkane + excess NH3 ethanolic -> amine
Heat in sealed container

Question 45

State synthesis to prepare amines from the reduction of nitriles

Answer 45

R-CN -> R-C-NH2
Pt catalyst + H2 gas
OR
LiAlH4 in dry ether

Question 46

State the reaction of reduction of nitrobenzene (catalyst and conditions)

Answer 46

Sn (s) catalyst
HCl (aqueous)
Heat under reflux

Nitrobenzene -> Benzene-NH2

Question 47

What does the reduction of nitrobenzene do to the benzene ring

Answer 47

Makes the benzene ring more reactive because nitro is electron withdrawing amine is electron donating

Question 48

How can amides be prepared?

Answer 48

acyl chloride + conc NH3
Ethanolic
Heat in sealed tube

Side product - ammonium chloride

Question 49

How are polyamides formed?

Answer 49

Condensation polymerisation where H2O or HCl is the side-product

Question 50

Compare and contrast the bromination of phenol with the bromination of benzene

Answer 50

• Both electrophilic substitution
• No need of a halogen carrier with phenol
• oxygens lone pair of electrons interacts with the benzene ring of delocalised electrons making electrophilic attack more likely
• tri-substitution of phenol compared to mono for benzene
• bromination of phenol requires bromine in aqueous solution but benzene rquires liquid bromine
• bromination of phenol requires room temperature but benzene requires heating (under reflux)

Question 51

Do any of the halogen’s lone pairs interact with the delocalised electrons in benzene ring?

Answer 51

No!

Question 52

Why might ethanoic anhydride be preferred over ethanoyl chloride in the synthesis of aspirin?

Answer 52

• cheaper
• less corrosive than ethanoyl chloride or HCl evolved from reaction
• reaction is less violent, vigorous, exothermic, dangerous
• less vulnerable to hydrolysis
• reaction is more easily controlled