Amines and Amino Acids (Chapter 27.1, 27.2)

Question 1

What are amines?

Answer 1

Organic compounds, derived from NH3, in which one or more hydrogen atoms in the NH3 have been replaced by a carbon chain or ring

Question 2

What is an aliphatic amine?

Answer 2

When the nitrogen atom is attached to at least one straight or branch carbon chain (alkyl group/R) e.g. methylamine, CH3NH2

Question 3

What is an aromatic amine?

Answer 3

When the nitrogen atom is attached to an aromatic ring (aryl group/Ar) e.g. phenylamine, C6H5NH2

Question 4

What are primary, secondary and tertiary amines?

Answer 4

• Primary: nitrogen attached to two hydrogens
• Secondary: nitrogen attached to one hydrogen
• Tertiary: nitrogen attached to zero hydrogens

Question 5

How do you name primary amines?

Answer 5

• NH2 at the end of the chain: alkyl-amine

- NH2 mid-chain: 2-amino-alkane

Question 6

How do you name secondary/tertiary amines containing the same alkyl group?

Answer 6

The prefixes di and tri are used to indicate the number of alkyl groups attached to the nitrogen atom e.g. di-methyl-amine

Question 7

How do you name secondary/tertiary amines when two or more different alkyl groups are attached to a nitrogen atom?

Answer 7

• The compound is named as an N-substutured derivative of the larger group
• e.g.CH3NHCH2Ch2CH3 = N-methyl-propyl-amine
• e.g. CH3N(CH2CH3)CH2CH2CH3 = N-ethyl-N-methyl-propylamine

Question 8

What do amines behave as in their chemical reactions?

Answer 8

Bases

Question 9

Why do amines behave as bases in their chemical reactions?

Answer 9

The lone pair of electrons on the nitrogen atom can accept a proton

Question 10

What happens when an amine accepts a proton?

Answer 10

• A dative covalent bond is formed between the lone pair of electrons on the nitrogen atom and the proton
• e.g. ethylamine => ethylammonium ion

Question 11

Describe salt formation with amines

Answer 11

• Amines are bases and they neutralise acids to make salts - e.g. methylamine reacts with HCl to form the salt methylammonium chloride (CH3NH3+Cl-)

Question 12

How are primary amines formed?

Answer 12

1) NH3 reacts with a haloalkane in a substitution reaction as the lone pair of electrons on the nitrogen atom allows NH3 to act as a nucleophile
2) this produces an ammonium salt
3) aqueous alkali is then added to generate the amine from the salt

Question 13

What are the two possible ways (equations) to form a primary amine?

Answer 13

1) CH3Cl + NH3 => CH3NH3+Cl-
CH3NH3Cl- + NaOH => CH3NH2 + NaCl + H2O
2) CH3Cl + 2NH3 => CH3NH2 + NH4Cl?

Question 14

What are the two conditions needed for the formation of (primary) amines?

Answer 14

1) ethanol is used as a solvent to prevent any substitution of the haloalkane by H2O and dissolves haloalkane better
2) excess NH3 is used to reduce further substitution of the amine group to form secondary and tertiary amines

Question 15

How are secondary and tertiary amines formed?

Answer 15

1) methylamine reacts further with a haloalkane in a substitution reaction as the lone pair of electrons on the nitrogen atom allows methylamine to act as a nucleophile
2) this forms a secondary amine
3) tertiary amines can also be formed by further reaction of the secondary amine

Question 16

How is phenylamine (C6H5NH2) made?

Answer 16

By the reduction of nitrobenzene (C6H5NO2)

Question 17

Describe the formation of phenylamine from nitrobenzene?

Answer 17

• Nitrobenzene is heated under reflux with tin (Sn) and HCl to form the ammonium salt, phenylammonium chloride
• Phenylammonium chloride is then reacted with excess NaOH to produce the aromatic amine, phenylamine
• Sn + HCl act as a reducing agent
• nitrobenzene + 6[H] => phenylamine + 2H2O

Question 18

What are amino acids?

Answer 18

Organic compounds with amine and carboxylic acid functional groups

Question 19

Describe alpha amino acids

Answer 19

• The amino acids in the body are all alpha amino acids in which the NH2 group is attached to the alpha carbon atom (the second carbon atom next to the carboxyl group)
• General forumula: RCH(NH2)COOH

Question 20

Why do amino acids have similar reactions to carboxylic acids and amines?

Answer 20

Because they have both an acidic COOH and basic NH2 functional group

Question 21

Describe the reaction of the amine group in an amino acid with acids

Answer 21

• The amine group on the amino acid is basic and reacts with acids to make salts
• e.g. the amino acid alanine reacts with HCl to form an ammonium salt:
  CH3CH(NH2)COOH + HCl => CH3CH(NH3+)COOHCl-

Question 22

Describe the reaction of the carboxyl group in an amino acid with aqueous alkalis

Answer 22

• The COOH group on the amino acid reacts with NaOH to form a salt and water
• e.g. glycine reacts with NaOH to form an Na salt:
  HCH(NH2)COOH + NaOH => HCH(NH2)COO-Na+ + H2O

Question 23

Describe the esterification reaction of the carboxyl group in an amino acid with alcohols

Answer 23

• Amino acids are easily esterified by heating with an alcohol in the presence of concentration H2SO4
• e.g. glycine reacts with excess ethanol and a small amount of H2SO4 - the COOH group is esterified, producing an ester and the acidic conditions protonate the basic NH2 group of the ester:
  HCH(NH2)COOH + C2H5OH + H+ => HCH(NH3+)COOC2H5 + H2O

Question 24

How are zwitterions formed?

Answer 24

When, within the structure of an amino acid, the basic NH2 group accepts a H+ from the COOH group to form an ion containing both a positive and negative charge (zwitterion)

Question 25

Why do zwitterions have no overall charge?

Answer 25

Bc the positive and negative charges cancel out

Question 26

What is the isoelectric point and why is it significant>

Answer 26

• The pH at which the zwitterion is formed
• Each amino acid has its own unique isoelectric point
• If an amino acid is added to a solution with a pH more than or less than its isoelectric point, the amino acid behaves as an acid/base and the NH3+/COO- lose/gains a proton

Question 27

What are amides?

Answer 27

• The products of reactions of acyl chlorides with NH3/amines
• They are common in nature e.g. in proteins, the bonds are amine groups

Question 28

What is the amide functional group?

Answer 28

CON - a carbonyl group bonded to oxygen

Question 29

What are primary, secondary and tertiary amides?

Answer 29

• Primary: nitrogen is bonded to two hydrogens e.g. propanamide
• Secondary: nitrogen is bonded to one hydrogen e.g. N-methylethanamide
• Tertiary: nitrogen is bonded to zero hydrogens e.g. N,N-dimethylmethanamide

Question 30

What are stereoisomers?

Answer 30

Compounds with the same structural formula but a different arrangement of atoms in space

Question 31

What is optical isomerism?

Answer 31

A type of stereoisomerism

Question 32

Where is optical isomerism found?

Answer 32

In molecules that contain a chiral centre

Question 33

What is a chiral centre?

Answer 33

A carbon atom attached to 4 different atoms/groups of atoms

Question 34

What does the presence of a chiral centre in a molecule lead to?

Answer 34

The existence of two non-superimposable mirror image structures

Question 35

What are enantiomers (optical isomers)?

Answer 35

Two molecules that are non-superimposable mirror image structures of each other (one isomer cannot be superimposed upon the other)

Question 36

What is there for each chiral carbon atom?

Answer 36

One pair of optical isomers

Question 37

What is the chiral carbon atom labelled with?

Answer 37

An asterisk (*)

Question 38

What do all alpha amino acids (except glycine) contain?

Answer 38

A chiral carbon atom, with the alpha carbon atom bonded to 4 different atoms/groups of atoms

Question 39

What does chirality apply to?

Answer 39

Any centre that holds attachments that can be arranged as two non-superimposable mirror image forms

Question 40

What atoms can chiral centres be?

Answer 40

Not just carbon atoms

Question 41

What are the bond angles in amines/ammonia?

Answer 41

107 degrees

Question 42

What is the equation for the reaction of methylamine with water?

Answer 42

CH3NH2 + H2O => CH3NH3OH

Question 43

Why is it difficult to produce primary amines using the nucleophilic substitution of haloalkanes?

Answer 43

It is difficult to control further substitution as the ethyl groups are activating ∴ the lone pair becomes increasingly electron dense

Question 44

What is the role of Sn in the reduction of nitrobenzene?

Answer 44

The electron donor

Question 45

What is the role of HCl in the reduction of nitrobenzene?

Answer 45

The proton donor

Question 46

What is the role of NaOH in the reduction of nitrobenzene?

Answer 46

To generate the free amine back again

Question 47

What is more basic, phenylamine or ethylamine?

Answer 47

Ethylamine as it has a very high electron density on the nitrogen and in phenylamine, the lone pair on the nitrogen is delocalised into the pi system

Question 48

What does the basicity of an amine depend on?

Answer 48

The electron density on nitrogen

Question 49

What two types of isomerism does stereoisomerism include?

Answer 49

Geometric and optical

Question 50

What three types of isomerism does structural isomerism include?

Answer 50

Chain, position and functional

Question 51

Why is ethylamine a stronger base than ethanamide?

Answer 51

• The amide bond is very stable and the C=O group is deactivating due to resonance
• The alkyl groups on ethylamine are activating

Question 52

What is the equation for the formation of ethanamide?

Answer 52

CH3COCl + 2NH3 => CH3CONH2 + NH4Cl

Question 53

Why is further substitution not a problem in the synthesis of amides?

Answer 53

Bc of the resonance in primary amides which stabilises the amide and prevents further substitution

Question 54

Why can amino acids be combined to give a variety of polypeptides?

Answer 54

There are 20 different types of alpha amino acids, each with different R groups, which can be combined in any order