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IB DP Physics 2025 Study Notes

2.2.3 Greenhouse Gases

Types of Greenhouse Gases

Methane (CH4)

Methane is one of the most effective greenhouse gases, capturing heat in the atmosphere with efficiency 25 times greater than CO2 over a 100-year period.

Natural Sources

  • Wetlands: The anaerobic decomposition of organic material in saturated soils produces methane as a by-product. These environments, teeming with microbial life, are significant contributors to atmospheric CH4.
  • Termites: These insects host microbes in their digestive systems that assist in breaking down wood and plant fibres, releasing methane.
  • Oceans: Methane is found in ocean waters and sediments, arising from biological activity and geothermal processes.
Diagram showing common greenhouse gases

Greenhouse gases

Image Courtesy BYJU’s

Human-Created Sources

  • Agriculture: Livestock farming, especially cattle, releases methane during digestion. Rice paddies, being anaerobic environments, are also CH4 sources.
  • Fossil Fuels: Natural gas consists mainly of methane. Its extraction, processing, and burning release CH4 into the atmosphere.
  • Landfills: The anaerobic decomposition of organic waste produces methane, which can escape into the atmosphere if not captured.

Water Vapour (H2O)

Water vapour is a crucial component of the Earth’s atmosphere and climate system, contributing to both heating and cooling mechanisms.

Natural Sources

  • Evaporation: Sunlight heats Earth’s surface, causing water from oceans, rivers, and lakes to evaporate into the atmosphere.
  • Transpiration: Plants release water vapour into the air, a process that cools plant tissues and brings underground water to the surface.

Human-Created Sources

  • Industry: Various industrial activities release water vapour, especially power plants that use steam for electricity generation.
  • Agriculture: Evaporation from irrigated fields contributes to atmospheric water vapour.

Carbon Dioxide (CO2)

Carbon dioxide plays a significant role in the greenhouse effect, being the most abundant anthropogenic greenhouse gas.

Natural Sources

  • Respiration: All aerobic organisms exhale CO2 as a by-product of cellular respiration.
  • Volcanic Eruptions: These natural events release gases trapped in the Earth’s crust, including significant amounts of CO2.

Human-Created Sources

  • Burning of Fossil Fuels: The primary human source, releasing billions of tonnes of CO2 into the atmosphere annually.
  • Deforestation: Trees absorb and store CO2. Their removal accelerates the increase of atmospheric CO2 levels.

Nitrous Oxide (N2O)

Nitrous oxide is a potent greenhouse gas, with a global warming potential 298 times greater than CO2 over a 100-year period.

Natural Sources

  • Soil: Specific microbial actions in soils, especially under conditions of high moisture and low oxygen, produce N2O.
  • Oceans: Oceanic processes involving nitrogen compounds result in the release of nitrous oxide.

Human-Created Sources

  • Agriculture: The use of synthetic and organic fertilisers increases N2O emissions from soil.
  • Combustion: The burning of fossil fuels and solid waste contributes to atmospheric N2O levels.

Absorption of Infrared Radiation

The energy absorption and re-emission mechanisms of greenhouse gases are crucial in regulating Earth’s temperature.

Diagram showing absorption of infrared radiations by greenhouse gases causing the greenhouse effect

Absorption of infrared radiations by greenhouse gases

Image Courtesy U.S. Energy Information Administration

Molecular Energy Levels

Each greenhouse gas has a distinct molecular structure that absorbs specific wavelengths of infrared radiation.

  • Vibrational Transitions: These are changes in the vibrational state of molecules, each absorbing energy at characteristic wavelengths.
  • Rotational Transitions: Molecular rotations absorb additional energy, with each gas having unique rotational energy levels.

Emission of Radiation

The absorbed energy is re-emitted, contributing to the greenhouse effect.

  • Isotropic Emission: Molecules release radiation uniformly, increasing Earth’s surface temperature.
  • Heat Trapping: The atmosphere captures some re-emitted radiation, preventing it from escaping into space.

Enhanced Greenhouse Effect

Human-induced increases in greenhouse gas concentrations amplify the natural greenhouse effect.

Burning of Fossil Fuels

The combustion processes associated with energy production and transportation are primary contributors.

  • CO2 Emissions: Coal-fired power plants, automobiles, and industrial processes are significant sources.
  • CH4 Emissions: Natural gas systems and petroleum production contribute to methane emissions.
  • N2O Emissions: Result from agricultural, transportation, and industrial activities.

Implications

Increased concentrations of greenhouse gases bring various environmental and climatic changes.

  • Rising Temperatures: Global average temperatures are increasing, with impacts on ecosystems and weather patterns.
  • Melting Ice Caps and Glaciers: Leads to rising sea levels and loss of habitat for cold-climate species.
  • Extreme Weather Events: The frequency and severity of storms, droughts, and heatwaves are escalating.

Through a detailed understanding of greenhouse gases, their sources, and impacts, strategies for mitigation and adaptation to climate change can be developed. Physics offers foundational insights and methodologies for addressing these global challenges, underscoring the discipline’s significance in contemporary environmental studies.

FAQ

Rising methane levels can have a significant impact on the ozone layer. When CH4 rises into the stratosphere, it undergoes a series of reactions catalysed by ultraviolet radiation, leading to the production of water vapour and ozone-depleting chemicals like chlorine. Increased water vapour in the stratosphere amplifies the greenhouse effect, while the produced chemicals contribute to ozone depletion. This process exacerbates global warming and increases the penetration of harmful ultraviolet rays to the Earth’s surface, affecting ecosystems and human health.

Water vapour plays a significant role in the feedback mechanisms that amplify the greenhouse effect. As the Earth’s surface warms due to increased concentrations of greenhouse gases, the rate of water evaporation rises, leading to a higher concentration of water vapour in the atmosphere. Since water vapour is a potent greenhouse gas, this increase amplifies the greenhouse effect, causing additional warming. This enhanced warming leads to further evaporation, establishing a positive feedback loop that contributes to accelerated global warming and associated climatic changes.

Technological advancements play a crucial role in mitigating N2O emissions from agriculture. Precision farming technologies, for example, ensure optimal application of fertilisers, reducing excess nitrogen in the soil that can be converted into N2O. Furthermore, development and use of nitrification and urease inhibitors can reduce N2O emissions by slowing the conversion of nitrogen compounds into nitrous oxide. Biotechnological innovations in developing crop varieties that utilise nitrogen more efficiently can also reduce the need for fertilisers, thereby decreasing potential N2O emissions.

The atmospheric concentration of CO2 experiences seasonal fluctuations primarily due to the natural processes of plant growth and decay. During the spring and summer, plants absorb more CO2 for photosynthesis, leading to a decrease in atmospheric CO2 levels. In autumn and winter, plant decay and reduced photosynthetic activity result in increased CO2 levels. Annually, there's a consistent rise in atmospheric CO2 concentrations, attributed to human activities such as burning fossil fuels and deforestation, which release large volumes of CO2, surpassing the natural absorption capacity of Earth’s ecosystems.

Different greenhouse gases have varied global warming potentials (GWPs) due to their distinct molecular structures and lifetimes in the atmosphere. For instance, methane (CH4) has a GWP over 25 times that of carbon dioxide (CO2) over a 100-year period, despite having a shorter atmospheric lifetime. Nitrous oxide (N2O), on the other hand, possesses a GWP nearly 300 times that of CO2 over the same timeframe. These disparities are attributed to the gases’ efficiency in trapping heat and their concentration in the atmosphere. The higher the GWP, the more significant the contribution to global warming.

Practice Questions

Explain how the molecular structure of greenhouse gases enables them to absorb and re-emit infrared radiation, leading to the greenhouse effect.

Greenhouse gases have specific molecular structures that enable them to absorb infrared radiation efficiently. The molecules vibrate and rotate at characteristic frequencies, transitioning between energy states. For instance, CO2 and CH4 molecules have multiple vibrational modes that allow them to absorb particular wavelengths of radiation. Once energised, these molecules re-emit the radiation isotropically. Some of the re-emitted radiation is directed back towards the Earth’s surface, contributing to the greenhouse effect, where the atmosphere traps heat, leading to a rise in the planet's average temperature.

Identify two human-created sources of methane (CH4) and discuss their contribution to the enhanced greenhouse effect.

Human-created sources of methane include agriculture and the extraction and burning of fossil fuels. In agriculture, livestock such as cattle produce methane during digestion, a process known as enteric fermentation. Additionally, rice paddies, being waterlogged, promote anaerobic conditions where methane-producing microbes thrive. The fossil fuel industry, especially natural gas and petroleum systems, emit methane during extraction, processing, and combustion. This release of excess methane enhances the greenhouse effect as methane is adept at trapping heat in the atmosphere, being over 25 times more effective than CO2 over a 100-year span, thus exacerbating global warming.

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