Crustal carbonate build-up as a driver for Earth’s oxygenation

Oxygenation of Earth’s atmosphere and oceans played a pivotal role in the evolution of the surface environment and life. It is thought that the rise in oxygen over Earth’s history was driven by an increasing availability of the photosynthetic limiting nutrient phosphate combined with declining oxyge...

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Bibliographic Details
Published in:Nature geoscience 2024-05, Vol.17 (5), p.458-464
Main Authors: Alcott, Lewis J., Walton, Craig, Planavsky, Noah J., Shorttle, Oliver, Mills, Benjamin J. W.
Format: Article
Language:English
Subjects:
704/2151
704/445/209
704/47/4113
Accumulation
Atmosphere
Biogeochemistry
Carbon
Carbon cycle
Carbon dioxide
Carbon dioxide concentration
Carbon isotope ratio
Carbon isotopes
Carbonates
Degassing
Earth
Earth and Environmental Science
Earth mantle
Earth Sciences
Earth System Sciences
Evolution
Extrasolar planets
Geochemistry
Geology
Geophysics/Geodesy
Inorganic carbon
Isotope ratios
Limiting factors
Nutrients
Oceanic crust
Oceans
Oxygen
Oxygenation
Phosphates
Phosphorus
Photosynthesis
Planetary temperature
Recycling
Volatile compounds
Volatiles
Weathering
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Summary:Oxygenation of Earth’s atmosphere and oceans played a pivotal role in the evolution of the surface environment and life. It is thought that the rise in oxygen over Earth’s history was driven by an increasing availability of the photosynthetic limiting nutrient phosphate combined with declining oxygen-consuming inputs from the mantle and crust. However, it has been difficult to assess whether these processes alone can explain Earth’s oxygenation history. Here we develop a theoretical framework for the long-term global oxygen, phosphorus and carbon cycles, incorporating potential trajectories for the emergence of continents, the degassing of mantle volatiles and the resulting increase in the size of the crustal carbonate reservoir. We find that we can adequately simulate the Earth’s oxygenation trajectory in both the atmosphere and oceans, alongside reasonable reconstructions of planetary temperature, atmospheric carbon dioxide concentration, phosphorus burial records and carbon isotope ratios. Importantly, this is only possible when we include the accumulation of carbonates in the crust, which permits ever-increasing carbon recycling rates through weathering and degassing. This carbonate build-up is a missing factor in models of Earth’s coupled climate, nutrient and oxygen evolution and is important for reconstructing Earth’s history and potential exoplanet biogeochemistry. The accumulation and subsequent recycling of carbonate in the crust may have helped to drive the oxygenation of the early Earth, according to an ocean and atmosphere box model incorporating the inorganic carbon cycle.
ISSN:1752-0894
1752-0908
DOI:10.1038/s41561-024-01417-1