What is the carbon cycle?

Carbon is one of the most abundant elements on Earth, which exists in many forms. This carbon is stored in reservoirs across the globe, including:

• the atmosphere

• oceans

• living things (also known as the ‘biosphere’)

• rocks and soils (also known as the ‘lithosphere’)

The carbon cycle is the movement of carbon between these reservoirs.

Carbon dioxide is very important in the carbon cycle. Most carbon in the atmosphere is carbon dioxide and it is important in many exchange processes between reservoirs. 

Methane is another important part of the carbon cycle, naturally emitted from wetlands and artificially from fossil fuels and agriculture. 

More complex molecules, such as volatile organic compounds, are also part of the carbon cycle, from both natural and artificial sources.

The carbon cycle is mostly a closed system, so it doesn’t lose or receive carbon from space. This means that if one reservoir loses carbon, other reservoirs will receive it.

There are many processes that move carbon between reservoirs.

QUESTION:

What happens when one reservoir in the carbon cycle loses carbon?

Why is the carbon cycle important?

The carbon cycle plays a key role in regulating Earth’s climate and making the planet habitable. By moving carbon out of the lithosphere, it becomes available to living things, making life possible.

We also know that carbon dioxide is the most important greenhouse gas produced by human activity, so its fate in the climate system is very important.

The movement of carbon from one reservoir to another can also slow down and spread out climatic changes caused by changes in carbon dioxide levels.

For example, human activity has released large quantities of carbon dioxide in the atmosphere, but oceans absorb some of this.

This reduces the impact on global temperatures, but has also led to ocean acidification, which threatens certain marine creatures and ecosystems.

Atmospheric carbon dioxide levels are now the highest they have been for at least 2 million years and still rising rapidly. Continued emissions of carbon dioxide into the atmosphere because of human activity risk disrupting the balance between different reservoirs in the carbon cycle.

This would cause changes to the processes of carbon transfer, leading to some of the many known impacts of climate change.

QUESTION:

Why is the carbon cycle crucial for Earth's habitability?

Why is the carbon cycle important?

The carbon cycle plays a key role in regulating Earth’s climate and making the planet habitable. By moving carbon out of the lithosphere, it becomes available to living things, making life possible.

We also know that carbon dioxide is the most important greenhouse gas produced by human activity, so its fate in the climate system is very important.

The movement of carbon from one reservoir to another can also slow down and spread out climatic changes caused by changes in carbon dioxide levels.

For example, human activity has released large quantities of carbon dioxide in the atmosphere, but oceans absorb some of this.

This reduces the impact on global temperatures, but has also led to ocean acidification, which threatens certain marine creatures and ecosystems.

Atmospheric carbon dioxide levels are now the highest they have been for at least 2 million years and still rising rapidly. Continued emissions of carbon dioxide into the atmosphere because of human activity risk disrupting the balance between different reservoirs in the carbon cycle.

This would cause changes to the processes of carbon transfer, leading to some of the many known impacts of climate change.

QUESTION:

What is one negative effect of oceans absorbing carbon dioxide?

Oceans in the carbon cycle

The oceans are key to the carbon cycle, with many processes that move carbon between oceans and other reservoirs.

One of the most simple interactions is gas exchange at the ocean surface.

Carbon dioxide in the atmosphere can dissolve in water, and naturally releases at a similar rate. This produces a store of carbon in surface waters, which interacts with photosynthesis and respiration as part of aquatic life.

The carbon store on the water’s surface is separated from the deep ocean by the thermocline.

The thermocline is a layer at roughly 1,000 metres down, which separates the turbulent, well-mixed surface waters from the calmer waters in the deep sea.

Carbon exchange between these zones is slower than with the atmosphere, but the deep sea is still a larger carbon reservoir because of its size.

Carbon in the ocean, including the deep ocean, can also react with sediment washed into the ocean from the land. This creates new rock deposits, largely of calcium carbonate. This moves carbon from the oceans into the lithosphere.

An increase in atmospheric carbon dioxide is resulting in greater absorption of carbon by the oceans, altering its chemistry.

QUESTION:

What is the thermocline in relation to the ocean's carbon cycle?

Oceans in the carbon cycle

The oceans are key to the carbon cycle, with many processes that move carbon between oceans and other reservoirs.

One of the most simple interactions is gas exchange at the ocean surface.

Carbon dioxide in the atmosphere can dissolve in water, and naturally releases at a similar rate. This produces a store of carbon in surface waters, which interacts with photosynthesis and respiration as part of aquatic life.

The carbon store on the water’s surface is separated from the deep ocean by the thermocline.

The thermocline is a layer at roughly 1,000 metres down, which separates the turbulent, well-mixed surface waters from the calmer waters in the deep sea.

Carbon exchange between these zones is slower than with the atmosphere, but the deep sea is still a larger carbon reservoir because of its size.

Carbon in the ocean, including the deep ocean, can also react with sediment washed into the ocean from the land. This creates new rock deposits, largely of calcium carbonate. This moves carbon from the oceans into the lithosphere.

An increase in atmospheric carbon dioxide is resulting in greater absorption of carbon by the oceans, altering its chemistry.

QUESTION:

Why is the deep ocean considered a larger carbon reservoir than surface waters?

Photosynthesis in the carbon cycle

Plants take in carbon dioxide as part of photosynthesis, converting it into sugars to use as food. This process removes a large amount of carbon from the atmosphere and locks it into plant biomass.

The absorption of carbon by photosynthesis forms the basis of most food chains, as animals often eat these plants.

Carbon stored in plants that don’t get eaten contributes to the richness of the soil, which can be stored for even longer.

Acidic soil with little oxygen slows the decay of organic matter, especially if it is waterlogged. This can become peat, which consists almost entirely of organic matter, storing the carbon it absorbed underground.

Over millions of years, this carbon-rich soil can become fossil fuels, such as coal, oil and gas, when it is buried by more sediment and subjected to heat and pressure underground.

Burning these fuels releases carbon that was originally absorbed from the atmosphere — when plants take in carbon dioxide through photosynthesis — often many hundreds of millions of years ago.

QUESTION:
What happens to carbon stored in plants that are not eaten?

Photosynthesis in the carbon cycle

Plants take in carbon dioxide as part of photosynthesis, converting it into sugars to use as food. This process removes a large amount of carbon from the atmosphere and locks it into plant biomass.

The absorption of carbon by photosynthesis forms the basis of most food chains, as animals often eat these plants.

Carbon stored in plants that don’t get eaten contributes to the richness of the soil, which can be stored for even longer.

Acidic soil with little oxygen slows the decay of organic matter, especially if it is waterlogged. This can become peat, which consists almost entirely of organic matter, storing the carbon it absorbed underground.

Over millions of years, this carbon-rich soil can become fossil fuels, such as coal, oil and gas, when it is buried by more sediment and subjected to heat and pressure underground.

Burning these fuels releases carbon that was originally absorbed from the atmosphere — when plants take in carbon dioxide through photosynthesis — often many hundreds of millions of years ago.

QUESTION:
How do fossil fuels relate to the carbon cycle and photosynthesis?