IB ESS HL - Carbon Stores in the Lithosphere (HL only) | Free Notes

Big picture: The lithosphere is the largest long-term carbon store on Earth. Carbon is locked in fossil fuels and carbonate rocks over millions of years.

Fossil fuels: Non-renewable energy sources (coal, oil, natural gas) formed from the remains of ancient organisms over millions of years under heat and pressure.
Coal: Formed from terrestrial plant material deposited in swamps, buried and compressed over 300+ million years (Carboniferous period).
Petroleum (oil) and natural gas: Formed from marine organisms (plankton, algae) deposited on ocean floors, buried under sediment, and transformed by heat and pressure.

Conditions required for fossil fuel formation

Rapid burial of organic matter before decomposition
Anaerobic conditions (absence of oxygen)
High pressure from overlying sediments
High temperatures over millions of years
Specific geological formations to trap hydrocarbons

Key concept: Limestone (CaCO3) is the largest carbon store in the lithosphere. It forms from the accumulation of marine organism shells and skeletons on the ocean floor.

How limestone forms

Marine organisms (corals, foraminifera, molluscs) build shells from calcium carbonate
When organisms die, shells accumulate on the ocean floor
Compaction and cementation over millions of years forms limestone
Chemical precipitation of CaCO3 from supersaturated water also contributes

Carbon cycling through limestone

Weathering releases CO2 back to the atmosphere (very slow)
Volcanic activity releases CO2 from subducted carbonate rocks
Ocean acidification dissolves carbonate, releasing stored carbon
Cement production liberates CO2 from limestone (fast, human-driven)

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Methane (CH₄): A potent greenhouse gas with approximately 80× the warming potential of CO₂ over 20 years, but a shorter atmospheric residence time (~12 years).
Methane clathrates: Ice-like structures on ocean floors and in permafrost that trap large quantities of methane. Also called methane hydrates.

Methane sources and feedback loops

Permafrost thawing releases trapped methane as temperatures rise
Warming oceans may destabilise methane clathrates on seafloor
Wetlands produce more methane as temperatures increase
This creates a positive feedback loop: warming → methane release → more warming

IB exam tip: Be able to explain the methane-climate positive feedback loop using systems language: stores, flows, and feedback mechanisms.

Big picture: The lithosphere is the largest long-term carbon store on Earth. Carbon is locked in fossil fuels and carbonate rocks over millions of years.

Fossil fuels: Non-renewable energy sources (coal, oil, natural gas) formed from the remains of ancient organisms over millions of years under heat and pressure.
Coal: Formed from terrestrial plant material deposited in swamps, buried and compressed over 300+ million years (Carboniferous period).
Petroleum (oil) and natural gas: Formed from marine organisms (plankton, algae) deposited on ocean floors, buried under sediment, and transformed by heat and pressure.

Conditions required for fossil fuel formation

Rapid burial of organic matter before decomposition
Anaerobic conditions (absence of oxygen)
High pressure from overlying sediments
High temperatures over millions of years
Specific geological formations to trap hydrocarbons

Key concept: Limestone (CaCO3) is the largest carbon store in the lithosphere. It forms from the accumulation of marine organism shells and skeletons on the ocean floor.

How limestone forms

Marine organisms (corals, foraminifera, molluscs) build shells from calcium carbonate
When organisms die, shells accumulate on the ocean floor
Compaction and cementation over millions of years forms limestone
Chemical precipitation of CaCO3 from supersaturated water also contributes

Carbon cycling through limestone

Weathering releases CO2 back to the atmosphere (very slow)
Volcanic activity releases CO2 from subducted carbonate rocks
Ocean acidification dissolves carbonate, releasing stored carbon
Cement production liberates CO2 from limestone (fast, human-driven)

See how examiners mark answers

Access past paper questions with model answers. Learn exactly what earns marks and what doesn't.

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Methane (CH₄): A potent greenhouse gas with approximately 80× the warming potential of CO₂ over 20 years, but a shorter atmospheric residence time (~12 years).
Methane clathrates: Ice-like structures on ocean floors and in permafrost that trap large quantities of methane. Also called methane hydrates.

Methane sources and feedback loops

Permafrost thawing releases trapped methane as temperatures rise
Warming oceans may destabilise methane clathrates on seafloor
Wetlands produce more methane as temperatures increase
This creates a positive feedback loop: warming → methane release → more warming

IB exam tip: Be able to explain the methane-climate positive feedback loop using systems language: stores, flows, and feedback mechanisms.

Carbon Stores in the Lithosphere (HL only)

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Carbon Stores in the Lithosphere (HL only)

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Related ESS HL Topics

IB Exam Questions on Carbon Stores in the Lithosphere (HL only)

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