The Haber Process (Cambridge (CIE) IGCSE Chemistry)

Revision Note

Alexandra Brennan

Written by: Alexandra Brennan

Reviewed by: Stewart Hird

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The Haber process

Extended tier only

  • Ammonia is manufactured in an exothermic reaction called the Haber process which occurs in five stages:

  • Stage 1

    • H2 is obtained from methane

    • N2 is obtained from the air

    • They are pumped into the compressor through a pipe

  • Stage 2 

    • Inside the compressor, the gases are compressed to around 20 000 kPa or 200 atmospheres 

  • Stage 3

    • The pressurised gases are pumped into a tank containing layers of an iron catalyst at a temperature of 450 °C

    • Some of the hydrogen and nitrogen react to form ammonia:

N2 (g) + 3H2 (g) ⇌ 2NH3 (g)

  • Stage 4

    • Unreacted H2 and N2 and the ammonia product pass into a cooling tank

    • The ammonia is liquefied and removed to pressurised storage vessels

  • Stage 5

    • The unreacted H2 and N2 gases are recycled back into the system and start over again

Diagram showing the Haber process

The production of ammonia by the Haber process

Worked Example

Ammonia is produced during the Haber Process. The reaction is summarised in the diagram below.

Flow chart type diagram summarising the Haber process
  1. Name gas A.

  2. Name catalyst B used and state why it is used

Answer:

  1. Gas A is hydrogen / H2.

  2. Catalyst B is iron, which is used to speed up the reaction / increase the rate of reaction.

Examiner Tips and Tricks

Examiners comment that students often know:

  • That nitrogen and hydrogen are needed for the Haber process

  • What the purpose of the catalyst is

But, that students do not:

  • Know where the nitrogen and hydrogen come from

  • Know the name of the catalyst and confuse it with other catalysts like 'vanadium oxide' and 'enzymes'.

You should know where the nitrogen and hydrogen come from as well as the conditions of the Haber process:

  • Pressure = 200 atmospheres

  • Temperature = 450 oC

  • Catalyst = iron 

Explaining the conditions in the Haber process

Extended tier only

  • Chemists' knowledge of the energy changes and factors affecting reaction rates can be used to predict the best possible conditions to make the most ammonia in the fastest possible time

  • However, sometimes those conditions are contradictory and choices have to be made between factors that improve the yield of ammonia and those that speed up the reaction

  • The graph below illustrates the effects of changing temperature and pressure on the yield of ammonia obtained

Graph showing the yield for the Haber process at different temperatures and pressures

The yield of ammonia produced changes with changes made to temperature and pressure

  • From the graph:

    • As the pressure increases, the percentage yield increases 

      • This is shown by following any of the curved lines  

    • As the temperature decreases, the percentage yield increases 

      • This is shown by following any vertical line upwards from the x-axisthat 

  • The actual conditions used must be chosen depending on a number of economical, chemical and practical considerations

Economic considerations

  • Like all industries, companies that manufacture and sell chemical goods do so to make a profit

  • Part of the industrial process is the economic decision on how and where to design and implement a manufacturing site

  • The availability and cost of raw materials is a major consideration which must be studied well before any decisions are taken

  • In the Haber Process the raw materials are readily available and inexpensive to purify:

    • Nitrogen - from the air

    • Hydrogen- from natural gas

  • If the cost of extraction of raw materials is too high or they are unavailable then the process is no longer economically viable

  • Many industrial processes require huge amounts of heat and pressure which is very expensive to maintain

  • Production energy costs are also a factor to be considered carefully and alongside the raw materials issue

Temperature: 450ºC

  • High temperature favours the reverse reaction as it is endothermic

    • So, a higher yield of reactants will be made

  • Low temperature favours the forward reaction as it is exothermic

    • So, a higher yield of products will be made

  • However, at low temperature the rate of reaction is very slow

  • So, 450 ºC is a compromise temperature between having a lower yield of products but being made more quickly

Pressure: 200 atm

  • Low pressure favours the reverse reaction as there are more moles of gaseous reactant

    • So, a higher yield of reactants will be made

  • High pressure favours the forward reaction as there are fewer moles of gaseous product

    • So, a higher yield of products will be made

  • However, high pressure can be dangerous and very expensive equipment is needed

  • So, 200 atmospheres is a compromise pressure between a lower yield of products being made safely and economically

Catalyst: Iron

  • The presence of a catalyst does not affect the position of equilibrium but it does increase the rate at which equilibrium is reached

  • This is because the catalyst increases the rate of both the forward and backward reactions by the same amount (by providing an alternative pathway requiring lower activation energy)

  • As a result, the concentration of reactants and products is nevertheless the same at equilibrium as it would be without the catalyst.

    So a catalyst is used as it helps the reaction reach equilibrium quicker

  • It allows for an acceptable yield to be achieved at a lower temperature by lowering the activation energy required

  • Without it the process would have to be carried out at an even higher temperature, increasing costs and decreasing yield as the higher temperature decomposes more of the NH3 molecules 

Examiner Tips and Tricks

The reaction conditions chosen for the Haber process are not ideal in terms of the yield but do provide balance between product yield, reaction rate and production cost.

These are called compromise conditions as they are chosen to give a good compromise between the yield, rate and cost.

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Alexandra Brennan

Author: Alexandra Brennan

Expertise: Chemistry

Alex studied Biochemistry at Newcastle University before embarking upon a career in teaching. With nearly 10 years of teaching experience, Alex has had several roles including Chemistry/Science Teacher, Head of Science and Examiner for AQA and Edexcel. Alex’s passion for creating engaging content that enables students to succeed in exams drove her to pursue a career outside of the classroom at SME.

Stewart Hird

Author: Stewart Hird

Expertise: Chemistry Lead

Stewart has been an enthusiastic GCSE, IGCSE, A Level and IB teacher for more than 30 years in the UK as well as overseas, and has also been an examiner for IB and A Level. As a long-standing Head of Science, Stewart brings a wealth of experience to creating Topic Questions and revision materials for Save My Exams. Stewart specialises in Chemistry, but has also taught Physics and Environmental Systems and Societies.