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The effects of gypsum deposits on ocean chemistry have been overlooked, says U of T's Ulrich Wortmann (iStock photo)

How ocean chemistry affects climate change

New research suggests "paradigm shift" in understanding

The words “climate change” may evoke images of humans and fossil fuels but scientists at the University of Toronto and the University of California Santa Cruz are pointing to another cause: the chemistry of the world’s oceans.

The cooling trend of the past 45 million years may have been caused by an event 50 million years ago that altered the world’s seawater, says U of T’s Professor Ulrich Wortmann in the Department of Earth Sciences.

“Seawater chemistry is characterized by long phases of stability, which are interrupted by short intervals of rapid change,” says Wortmann, lead author of a study to be published in Science this week.

“We’ve established a new framework that helps us better interpret evolutionary trends and climate change over long periods of time. The study focuses on the past 130 million years, but similar interactions have likely occurred through the past 500 million years.”

Wortmann and co-author Adina Paytan of the Institute of Marine Sciences at the University of California Santa Cruz point to the collision between India and Eurasia approximately 50 million years ago as one example of an interval of rapid change.

This collision enhanced dissolution of the most extensive belt of water-soluble gypsum on Earth, stretching from Oman to Pakistan, and well into Western India – remnants of which are well exposed in the Zagros mountains.

The authors suggest that the dissolution or creation of such massive gypsum deposits changes the sulfate content of the ocean. This in turn affects the amount of sulfate aerosols in the atmosphere and thus climate.

“We propose that times of high sulfate concentrations in ocean water correlate with global cooling, just as times of low concentration correspond with greenhouse periods,” says Paytan.

“When India and Eurasia collided, it caused dissolution of ancient salt deposits which resulted in drastic changes in seawater chemistry,” Paytan continues. “This may have led to the demise of the Eocene epoch – the warmest period of the modern-day Cenozoic era – and the transition from a greenhouse to icehouse climate, culminating in the beginning of the rapid expansion of the Antarctic ice sheet.”

The researchers combined data of past seawater sulfur composition, assembled by Paytan in 2004, with Wortmann’s recent discovery of the strong link between marine sulfate concentrations and carbon and phosphorus cycling. They were able to explain the seawater sulfate isotope record as a result of massive changes to the accumulation and weathering of gypsum – the mineral form of hydrated calcium sulfate.

“While it has been known for a long time that gypsum deposits can be formed and destroyed rapidly, the effect of these processes on seawater chemistry has been overlooked,” says Wortmann. “The idea represents a paradigm shift in our understanding of how ocean chemistry changes over time and how these changes are linked to climate.”

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