Surprising discovery shows a strong link between Earth's magnetic field and atmospheric oxygen levels

Sanjukta Mondal
contributing writer

Sadie Harley
scientific editor

Robert Egan
associate editor

Every breath we take in contains 21% oxygen, the gas that makes life on Earth possible. Oxygen, in its combined oxide state, has always been abundant in Earth's crust, but elemental diatomic oxygen became part of our atmosphere around 2.4 to 2.5 billion years ago as a gift from cyanobacteria, which triggered the Great Oxidation Event and breathed life into Earth.
A between NASA Goddard Space Flight Center and the University of Leeds discovered that the Earth's magnetic field strength and atmospheric oxygen levels over the past 540 million years have seemed to spike and dip at the same time, showing a strong, statistically significant correlation between the two.
This correlation could arise from unexpected connections between geophysical processes in Earth's deep interior, redox reactions on Earth's surface, and biogeochemical cycling.
According to findings published in Science Advances, both magnetic field strength and atmospheric oxygen levels reached their peak intensities between 330 and 220 million years ago.
Scientists have long speculated that Earth's magnetic field may play a role in making the planet habitable, a hypothesis reinforced by paleomagnetic records that show that the existence of a geomagnetic field overlaps with the timeline of life's emergence. However, there has been little direct evidence of a long-term connection, as most Earth system models don't even include the geomagnetic field when studying how oxygen levels in the atmosphere have changed over time.

Previous simulations have shown that the magnetic field may be responsible for preventing the atmosphere from being stripped away or eroded by space activity, such as ionization and ohmic heating, arising from solar winds and solar energetic particles. However, there is a lack of side-by-side comparison of long-term magnetic field and oxygen level records.
This study set out to uncover the statistically significant link between both factors by analyzing two completely independent data sets: paleomagnetic records or geomagnetic data preserved in rocks and minerals for virtual geomagnetic axial dipole moment (VGADM) and various geochemical proxies for atmospheric oxygen, such as fossilized charcoal in sediments and ocean anoxia data.
The findings reveal the highest correlation, 0.72, between Earth's geomagnetic dipole and atmospheric oxygen levels over the last 540 million years. The highest value occurred when there was no time gap between the two, and even after removing long-term trends, the connection remained strong, with only a slight lag of about 1 million years, which is considered negligible on a colossal geological timescale.
This link suggests a deep, previously unrecognized connection between Earth's interior and the surface environment that supports life.
These findings enhance our understanding of Earth's evolutionary history and provide deeper insight into what makes our planet habitable, offering valuable clues in the search for life beyond Earth.
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More information: Weijia Kuang et al, Strong link between Earth's oxygen level and geomagnetic dipole revealed since the last 540 million years, Science Advances (2025).
Journal information: Science Advances
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