News Release

Syracuse University geologists confirm oxygen levels of ancient oceans

Using a novel approach called iodine geochemistry, Zunli Lu, Xiaoli Zhou and their colleagues have confirmed the earliest appearance of dissolved oxygen in the ocean's surface waters

Peer-Reviewed Publication

Syracuse University

Zunli Lu, Syracuse University

image: Assistant Professor Zunli Lu co-authored the study. view more 

Credit: Syracuse University News Services

Geologists in the College of Arts and Sciences have discovered a new way to study oxygen levels in the Earth's oldest oceans.

Zunli Lu and Xiaoli Zhou, an assistant professor and Ph.D. student, respectively, in the Department of Earth Sciences, are part of an international team of researchers whose findings have been published by the journal Geology (Geological Society of America, 2014). Their research approach may have important implications for the study of marine ecology and global warming.

"More than 2.5 billion years ago, there was little to no oxygen in the oceans, as methane shrouded the Earth in a haze," says Lu, a member of Syracuse University's Low-Temperature Geochemistry Research Group. "Organisms practicing photosynthesis eventually started to overpower reducing chemical compounds [i.e., electron donors], and oxygen began building up in the atmosphere. This period has been called the Great Oxidation Event."

Using a novel approach called iodine geochemistry, Lu, Zhou and their colleagues have confirmed the earliest appearance of dissolved oxygen in the ocean's surface waters.

Central to their approach is iodate, a form of iodine that exists only in oxygenated waters. When iodate is detected in carbonate rocks in a marine setting, Lu and company are able to measure the elemental ratio of iodine to calcium. This measurement, known as a proxy for ocean chemistry, helps them figure out how much oxygen has dissolved in the water.

"Iodine geochemistry enables us to constrain oxygen levels in oceans that have produced calcium carbonate minerals and fossils," says Lu, who developed the proxy. "What we've found in ancient rock reinforces the proxy's reliability. Already, we're using the proxy to better understand the consequences of ocean deoxygenation, due to rapid global warming."

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In addition to Lu and Zhou, the article was co-authored by Dalton S. Hardistry, a graduate student at the University of California, Riverside; Noah J. Planavsky, assistant professor of geology and geophysics at Yale University; Andrey Bekker, assistant professor of geological sciences at the University of Manitoba (Canada); Pascal Philippot, professor of physics at the University of Denis Diderot in Paris (France); and Timothy W. Lyons, professor of biogeochemistry at UC Riverside.


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