Study Uncovers Key to Delayed Climate Recovery Following Mass Extinction Event

Sofia Rauzi (left) and Dr. Terry Isson (right) conducting fieldwork in Svalbard. (Image credit: B. Beaty/University of Waikato)

A study led by a University of Waikato Ph.D. student has shed light on the cause of delayed climate recovery following Earth’s most severe extinction event 251 million years ago—a discovery that will contribute to our understanding of the global climate system.

Published in the multidisciplinary journal Proceedings of the National Academy of Sciences (PNAS) by lead researcher Sofia Rauzi, this research reveals the role marine clay formation had in slowing the Earth’s return to baseline temperatures after the end-Permian mass extinction.

Earth’s climate system is generally viewed to recover in the order of 100,000 years following a significant carbon injection event such as the volcanic eruption that triggered the end-Permian mass extinction.

“Climate recovery following the end-Permian took over five million years, so we set out to investigate why temperatures stayed warm for so long,” says Ms Rauzi. 

Analysis of the chemical composition of rocks from New Zealand, Japan, and Norway indicates that increased marine clay formation, also known as reverse weathering, contributed to the sustained high temperatures. 

Reverse weathering, which releases CO2, involves the formation of clays in the ocean and traps carbon in the ocean and atmosphere. These findings suggest that reverse weathering has played an integral role in regulating Earth’s climate. 

This study provides new insights into the Earth’s carbon-silica cycle and climate dynamics during the Early Triassic. We now have evidence that reverse weathering was crucial in maintaining high CO2 levels and temperatures, which has implications for understanding current climate processes.

Ms. Rauzi’s supervisor, University of Waikato Senior Lecturer Dr. Terry Isson, says it’s essential that we understand how Earth’s natural thermostat operates.

“Marine clay formation likely plays a critical role in regulating climate, and yet there is so much we don’t understand about this process, which is a key focus of our research,” Dr. Isson says. 

Ms. Rauzi is based at the University of Waikato’s Tauranga campus and moved to New Zealand from the United States in 2022 to pursue her Ph.D. after being inspired by Dr. Isson’s line of research. 

Ms. Rauzi is the recipient of the 2024 L’Oréal-UNESCO for Women in Science (FWIS) Fellowship, through which she is mentored on navigating a career in science. 

Each year, the program recognizes the achievements of exceptional female scientists at different stages of their careers and awards them with fellowships to help further their research. There is one fellowship available in New Zealand each year. 

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