Syllabus Edition

First teaching 2020

Last exams 2024

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Nitrogen Compounds (A Level Only) (CIE A Level Chemistry)

Exam Questions

2 hours10 questions
1a3 marks

This question is about the synthesis and nature of amines.

State the reagents and conditions required for the conversion of 1-bromobutane into butylamine.

1b1 mark

Explain why amines can act as bases.

1c2 marks

Write an equation to show how ethylamine acts as a base when reacted with hydrochloric acid and give the name of the product formed in this reaction.

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2a1 mark

This question is about amino acids.

State the general formula for an amino acid.

2b2 marks

The amino acid alanine is shown in Fig. 2.1

alanine

Fig. 2.1


Draw the two structures of alanine in acidic and basic conditions. 











acidic conditions











basic conditions

2c1 mark

Electrophoresis is an analytical technique which separates ions by placing them in an electrical field.

Describe briefly how a sample of an amino acid can be separated using this technique.

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3a1 mark

Amides can be formed from amines. An example is shown in the following reaction scheme where compound X reacts with methylamine to form N-methyl propanamide and hydrogen chloride.


compound X + CH3NH2 → CH3CH2CONHCH3 + HCl

State the structural formula of compound X.

3b1 mark

N-methyl propanamide can undergo reduction forming compound Y and water. State the reagent required for this reaction.

Reagent .................................................................

3c1 mark

A different amide, ethanamide was heated with sodium hydroxide the gas ammonia is formed along with one other product.

i)
Write the equation for this reaction.
[1]
ii)
Explain how this reaction could be used as a test for an amide.
[2]

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1a7 marks

Three nitrogen containing molecules, ammonia, NH3, phenylamine, C6H5NH2 and N-methylethylamine, CH3CH2NHCH3, are drawn below respectively in Fig. 1.1.

7-6-1a-m-three-amine-molecules

Fig. 1.1

i)
List the three amine molecules drawn in Fig. 1.1 in order of increasing base strength.

[1]

ii)
Explain your answer to part (b) (i).

[6]

1b3 marks

Phenylamine, C6H5NH2 shown in Fig. 1.1 in part (a) can be produced from nitrobenzene, C6H5NO2

Name the type of reaction and suggest suitable reagents and conditions for this conversion.

1c2 marks

Azo dyes are organic compounds, which are largely used in the treatment of textiles and leather products, as well as in food. Phenylamine, C6H5NH2, can be used in the manufacture of azo dyes. 

The manufacturing process is outlined below.

Step 1

Phenylamine is dissolved in HCl to produce a diazonium salt. A diazonium salt contains two nitrogen atoms joined together by a triple bond. The reaction for this process is as follows:

C6H5NH2  +  HCl   +  HNO2   →    C6H5N2+Cl-    +   2H2O
Step 2

This solution is then slowly added to an alkaline solution of a phenol coupling agent to
form the dye. 

i)
The diazonium salt, C6H5N2+Cl-, is an unstable compound. Suggest a condition that could be added to ensure that the salt would not break down during the reaction.

[1]

ii)
Draw the structure of the diazonium salt formed in Step 1, showing the displayed formula of the nitrogen containing group.

[1]

1d2 marks

Phenol, C6H5OH, is an aromatic organic compound which is also crucial in the manufacture of azo dyes.

The final step of the azo dye production involves pairing up the diazonium salt with a phenol compound as a coupling agent. 

Suggest a structure for the azo dye if the coupling agent used is 2,6-dimethylphenol. 

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2a6 marks

Amines will react with acid chlorides to produce a different nitrogen containing product.

i)
Name and outline the mechanism between ethanoyl chloride, CH3COCl and methylamine, CH3NH2.

[5]

ii)
Give the IUPAC name of the compound formed in the reaction.

[1]

2b4 marks

Methylamine can be prepared from chloromethane.

i)
Give the other reagent, and any reaction conditions necessary for the preparation of methylamine.

[3]

ii)
Give the name of the mechanism between chloromethane and the other reagent to form methylamine.

[1]

2c2 marks

Chloroethane can also react with methylamine.

i)
Draw the displayed formula of the organic compound formed in this reaction.

[1]

ii)
Give the classification of this compound.

[1]

2d4 marks

Two separate solutions of methylamine, CH3NH2 and dimethylamine, (CH3)2NH, were left unlabelled in a laboratory.

i)
Suggest how, other than smell, they could be distinguished from one another.

[2]

ii)
Give an explanation to your answer to part (i).

[2]

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3a1 mark

Much research has been carried out in recent years investigating the exact structure of silk. The silk of a spider's web is at least five times as strong as steel, and twice as elastic as nylon. A silk fibre is composed of many identical protein chains, which are mainly made from the amino acids glycine, alanine and serine, shown in Fig. 3.1, with smaller amounts of four other amino acids.

7-6-3a-m-amino-acids

Fig. 3.1

Amino acids can exist as zwitterions. Draw the zwitterion structure for glycine.

3b2 marks

Amino acids can act as acids or bases. Write equations to show:

i)
the reaction between alanine and HCl (aq),

[1]

ii)
the reaction between serine and NaOH (aq).

[1]

3c4 marks
i)
Draw the structural formula of a portion of the silk protein, showing three main acid residues. Label a peptide bond on your structure.

[3]

ii)
State the polymer type of silk protein.

[1]

3d
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3 marks

The Mr of a silk protein molecule is about 600,000. Assuming it is made from equal amounts of the three amino acids in Fig. 3.1, calculate the average number of amino acid residues in the protein chain.
Show your working.

[Mr (glycine) = 75;   Mr (alanine) = 89;     Mr (serine) = 105]

number of residues .............................................

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4a4 marks

Phenylamine can be converted into the organic compounds A and B as shown in Fig. 4.1.

7-6-4a-m-reactions-of-phenylamine-a

Fig. 4.1

i)
Suggest the structural formulae of A and B in the boxes in Fig. 4.1.

[2]

ii)
Suggest suitable reagents and conditions for step 1, and write them in the box over the arrow in Fig. 4.1.

[2]

4b
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3 marks

When phenylamine is treated with propanoyl chloride a white crystalline compound, C, C9H11NO, is formed.

i)
Name the functional group formed in this reaction.

[1]

ii)
Calculate the percentage by mass of nitrogen in C.

[1]

percentage = ........................ %

iii)
Draw the structural formula of C.

[1]

4c4 marks

Benzamide can be reduced to form benzylamine.

benzamide benzylamine
benzamide benzylamine



i)
State which is the weaker base, benzamide or benzylamine. Explain your answer.

[3]

ii)
Give a suitable reducing agent required for this reduction.

[1]

4d2 marks

When benzamide is refluxed with acid, hydrolysis occurs.

i)
Draw the structural formula of the resulting organic compound.

[1]

ii)
State the name of the other product formed during this hydrolysis reaction.

[1]

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5a2 marks

A mixture of amino acids may be separated using electrophoresis. A typical practical set-up is shown in the diagram.

7-6-5a-m-electrophoresis

When the power supply is switched on, some amino acids may not move, but remain stationary. Suggest an explanation for this observation.

5b1 mark

The amino acid glycine has the formula H2NCH2CO2H. Identify the species formed on the filter paper if glycine moves to the left (positive) end of the filter paper.

5c3 marks

The result shown in Fig. 5.1 was obtained from another electrophoresis. 

electrophoresis-result

Fig. 5.1

What can be deduced about the relative sizes of, and charges on, the amino acid species A, B and C?

amino acid relative size charge
A    
B    
C    

5d3 marks

A tripeptide was formed from three different amino acids, alanine, serine and valine. The structural formulae of the amino acids are shown in Table 5.1.

Table 5.1

amino acid structural formulae
alanine H2NCH(CH3)CO2H
serine H2NCH(CH2OH)CO2H
valine H2NCH(CH(CH3)2)CO2H

i)
How many different tripeptides can be made using one molecule of each of the amino acids in Table 5.1?
[2]
ii)
Draw the tripeptide, showing the peptide bonds in displayed form.

[1]

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