Syllabus Edition

First teaching 2024

First exams 2026

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Acid Rain (DP IB Environmental Systems & Societies (ESS))

Revision Note

Acid Rain Formation

  • Acid rain refers rainfall that has a pH lower than normal rainwater

    • Regular rain has a pH between 5 and 5.5, meaning it is naturally slightly acidic

    • Acid rain is more acidic, has a pH lower than 5, and is frequently the result of human activity

Chemical reactions leading to acid rain

  • Nitrogen oxides (NOx) and sulphur dioxide (SO2) are the main gases responsible for acid rain

    • These gases react with water and oxygen in the atmosphere to form nitric acid and sulfuric acid

Formation of nitric acid

  • Nitrogen oxides are mainly produced from vehicle exhausts

  • The reactions are as follows:

    • Nitrogen monoxide (NO) reacts with oxygen (O2) to form nitrogen dioxide (NO2)

2NO + O2 → 2NO2

  • The nitrogen dioxide then reacts with water (H2O) and oxygen in the air to produce nitric acid (HNO3)

4NO2 + O2 + 2H2O → 4HNO3

Formation of sulphuric acid

  • Sulphur dioxide is produced by burning fossil fuels and reacts with water in the atmosphere

  • The reactions are as follows:

    • Sulphur dioxide (SO2) dissolves in rainwater, producing sulphurous acid (H2SO3)

SO2 ​+ H2​O → H2​SO3

  • The sulphurous acid is then oxidised by oxygen in the air to produce sulfuric acid (H2SO4)

2H2SO3 + O2 → 2H2SO4

Types of deposition

  • Wet deposition refers to acidic precipitation falling to Earth in the form of rain, snow, or fog

  • Sulphuric acid and nitric acid can also combine with ash and other particles present in the air, forming dry particles (i.e. acidic dust and gases)

    • Dry deposition occurs when these particles settle on surfaces, including vegetation, buildings, cars and soil

Diagram explaining acid rain formation and its effects. Depicts industrial emissions leading to acid rain damaging forests, acidifying soil, and causing lake eutrophication.
Causes of acid deposition

Acid Rain Impacts

Impacts on ecology

Impacts on terrestrial habitats

  • Acidic deposition from acid rain accelerates the leaching of essential nutrients from soil, such as calcium, magnesium and potassium

    • Leaching of these nutrients reduces their availability for plants

    • This leads to nutrient deficiencies

    • This reduces plant growth and overall ecosystem productivity

  • Acidic rain can increase soil toxicity

    • This can occur by mobilising harmful metals like aluminium

    • This damages plant roots and affects their ability to absorb water and nutrients

  • Acid rain causes direct damage to foliage

    • This weakens trees, making them more vulnerable to disease and harsh weather

  • Coniferous forests, e.g. forests of pine or spruce trees, are sensitive to acid rain

    • This is due to their shallow root systems and thin bark

    • Acid rain also damages their foliage and inhibits nutrient absorption

Illustration of tree with leaves being damaged by acid rain from a dark cloud above. Text on the image reads "DIRECT LEAF DAMAGE".
Acid rain directly affects plants by damaging the leaves and roots

Impacts on freshwater habitats

  • Acid rain can make water bodies more acidic

  • This is due to a process referred to as solubilisation of aluminium

    • Acid rain causes aluminium, which is normally bound in the soil, to dissolve

    • This allows the aluminium to enter nearby water bodies

  • This aluminium is toxic to aquatic life, such as fish and freshwater invertebrates

    • Fish gills can become coated with aluminium

      • This makes it harder for them to breathe

    • Some invertebrates with exoskeletons may have difficulty maintaining their protective shells

      • They rely on calcium to build and maintain their hard outer shells

      • When acid rain increases the acidity of water, it reduces the availability of calcium and other minerals that these organisms need

      • This makes it harder for them to properly develop or maintain their exoskeletons

Impacts on buildings and infrastructure

Corrosion of construction materials

  • Acid rain erodes materials like marble, limestone, steel, and paint used in buildings and monuments

  • Marble and limestone both contain calcium carbonate (CaCO3)

  • The calcium carbonate reacts with sulphuric acid or nitric acid, causing stonework to corrode and weaken

    • For example, the Taj Mahal in India, made of marble, has shown signs of erosion and discolouration due to acid rain

    • Acid rain has also had an impact on historical statues and structures, such as those in Rome and Greece

Diagram showing acid rain damaging structures: a temple and statue's CaCO3 surfaces crumbling, and an iron structure corroding and rusting (Fe).
The impact of acid rain can be seen on buildings, statues and metallic structures, particularly in polluted cities

Impacts on human health

Respiratory issues

  • Acid rain does not directly harm humans

  • However, nitrate and sulphate particles from acid rain can cause respiratory problems

    • PM2.5 particles (tiny air pollutants) from acid rain can enter the lungs

    • This leads to:

      • Tissue damage

      • Lung inflammation

      • An increased risk of conditions such as asthma and bronchitis

    • As a result, areas with heavy industrial activity, such as parts of China and Eastern Europe, experience greater respiratory health risks

Acid Rain Management Strategies

  • There are three main levels of pollution management strategies:

    1. Changing human activity

    2. Regulating and reducing quantities of pollutants released at the point of emission

    3. Cleaning up the pollutants and restoring the ecosystem after pollution has occurred

Diagram showing the main strategies for managing the impacts of pollution
The main strategies for managing the impacts of pollution
  • These levels can also be applied to acid rain management strategies

    • Acid rain requires effective pollution management strategies to mitigate its harmful effects on the environment and human health

1. Altering human activity

  • Reducing the consumption of fossil fuels is a key strategy to minimise acid rain

    • Encourage the use of alternative energy sources, such as renewable energy, can significantly reduce emissions of sulphur dioxide and nitrogen oxides

  • International agreements and national governments play a vital role in:

    • Promoting sustainable practices

    • Supporting the development of clean technologies

    • Lobbying for emissions reductions

2. Regulating and monitoring pollutant release

  • Government regulations and monitoring systems are essential to control and reduce the release of pollutants that contribute to acid rain

    • Coal-burning power plants and vehicles are major sources of sulphur dioxide and nitrogen oxide emissions

    • Installing pollution control devices such as scrubbers and catalytic converters can effectively remove these pollutants from emissions

3. Clean-up and restoration measures

  • In areas heavily affected by acid rain, certain strategies may be used to mitigate the damage caused

    • For example, spreading ground limestone or lime in acidified lakes and rivers can neutralise acidity and restore the water's pH balance

  • Restoring damaged ecosystems can also be achieved through re-colonisation efforts, such as planting acid-tolerant vegetation

    • This can help restore ecological balance to these damaged ecosystems

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Alistair Marjot

Author: Alistair Marjot

Expertise: Biology & Environmental Systems and Societies

Alistair graduated from Oxford University with a degree in Biological Sciences. He has taught GCSE/IGCSE Biology, as well as Biology and Environmental Systems & Societies for the International Baccalaureate Diploma Programme. While teaching in Oxford, Alistair completed his MA Education as Head of Department for Environmental Systems & Societies. Alistair has continued to pursue his interests in ecology and environmental science, recently gaining an MSc in Wildlife Biology & Conservation with Edinburgh Napier University.

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