Mysterious climate behavior during Earth’s most severe mass extinction event explained

rw_s. Credit: Nature Communications (2022). DOI: 10.1038/s41467-022-31128-3″ width=”800″ height=”530″/>

Mineralogical data across the extinction event. Mineralogical data from (A) Ubara and (B) Akkamori. Quartz (qtz); pyrite (pyr); bertierine (bth); Fe-ilite; and frw_s. Credit: Nature Communications (2022). DOI: 10.1038/s41467-022-31128-3

The end-Permian mass extinction is the most severe mass extinction event ever recorded, during which ~80% of marine species went extinct.

While the beginning of this extinction event was driven by an extreme and rapid warming event, recovery of both global climate and ecosystems was extremely sluggish. Temperatures remained lethally hot and ecosystems depleted for over 5 million years.

Based on our current understanding of how the carbon cycle and climate operates, temperatures ought to have recovered much more quickly.

This delayed recovery stands out from all other known mass extinction events, and has baffled scientists for many years without any real explanation.

A recently released paper published by Nature Communications“Marine siliceous ecosystem decline led to sustained anomalous early Triassic warmth,” by University of Waikato researchers Terry Isson and Sofia Rauzi from the Earth-Life Interactions (ELI) research group, suggesting that the decline of silica secreting marine organisms this event both exacerbated climate change and was responsible for the 5 million year delay in global temperature recovery.

This provides for the first time, an comprehensive explanation for why it took so long for temperatures to recover to what they were before the mass extinction event.

Clay minerals form in the oceans and in the process release CO2. Clays minerals are fundamentally made up of silica and so cannot form without it. Silica secreting organisms compete for this silica, meaning that a healthy siliceous ecosystem that uses large amounts of silica will act to lower the amount of CO2 released from clay mineral formation.

It is well established that there was widespread loss of silica secreting organisms in the oceans during the end-Permian mass extinction event, and that these organisms did not recover for 5 million years. This research demonstrates, using a carbon cycle model and also mineralogical analysis, that this would have led to increased CO2 Release into the atmosphere during this time, keeping temperatures on Earth high for a prolonged period of time.

This research provides the first ever direct evidence that silica secreting organisms play a very prominent role in regulating climate on Earth that has previously never been recognized.


Rethinking planetary climate controls


More information:
Terry T. Isson et al, Marine siliceous ecosystem decline led to sustained anomalous early Triassic warmth, Nature Communications (2022). DOI: 10.1038/s41467-022-31128-3

Provided by University of Waikato

Citation: Mysterious climate behavior during Earth’s most severe mass extinction event explained (2022, June 21) retrieved 21 June 2022 from https://phys.org/news/2022-06-mysterious-climate-behavior-earth-severe.html

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