So when and where did O₂begin to build up on Earth?

By studying ancient rocks, researchers have determined that sometime between 2.5 and 2.3 billion years ago, Earth underwent what scientists call the "Great Oxidation Event" or "GOE" for short. O₂first accumulated in Earth's atmosphere at this time and has been present ever since.

Through numerous studies in this field of research, however, evidence has emerged that there were minor amounts of O₂小范围的地球古代浅海洋before the GOE. And in a study published recently in the journalNature Geoscience, a research team led by scientists at Arizona State University (ASU) has provided compelling evidence for significant ocean oxygenation before the GOE, on a larger scale and to greater depths than previously recognized.

For this study, the team targeted a set of 2.5 billion-year-old marine sedimentary rocks from Western Australia known as the Mt. McRae Shale. "These rocks were perfect for our study because they were shown previously to have been deposited during an anomalous oxygenation episode before the Great Oxidation Event," says lead author Chadlin Ostrander of ASU's School of Earth and Space Exploration.

Shales are sedimentary rocks that were, at some time in Earth's past, deposited on the sea floor of ancient oceans. In some cases, these shales contain the chemical fingerprints of the ancient oceans they were deposited in.

For this research, Ostrander dissolved shale samples and separated elements of interest in a clean lab, then measured isotopic compositions on a mass spectrometer. This process was completed with the help of co-authors Sune Nielsen at Woods Hole Oceanographic Institution (Massachusetts); Jeremy Owens at Florida State University; Brian Kendall at the University of Waterloo (Ontario, Canada); scientists Gwyneth Gordon and Stephen Romaniello of ASU's School of Earth and Space Exploration; and Ariel Anbar of ASU's School of Earth and Space Exploration and School of Molecular Sciences. Data collection took over a year and utilized facilities at Woods Hole Oceanographic Institution, Florida State University, and ASU.

Using mass spectrometers, the team measured the thallium and molybdenum isotope compositions of the Mt. McRae Shale. This was the first time both isotope systems had been measured in the same set of shale samples. As hypothesized, a predictable thallium and molybdenum isotope pattern emerged, indicating that manganese oxide minerals were being buried in the sea floor over large regions of the ancient ocean. For this burial to occur, O₂needed to have been present all the way down to the sea floor 2.5 billion-years-ago.

These findings improve scientists' understanding of Earth's ocean oxygenation history. Accumulation of O₂was probably not restricted to small portions of the surface ocean prior to the GOE. More likely, O₂accumulation extended over large regions of the ocean and extended far into the ocean's depths. In some of these areas, O₂accumulation seems to have even extended all the way down to the sea floor.

"Our discovery forces us to re-think the initial oxygenation of Earth," states Ostrander. "Many lines of evidence suggest that O₂started to accumulate in Earth's atmosphere after about 2.5 billion years ago during the GOE. However, it is now apparent that Earth's initial oxygenation is a story rooted in the ocean. O₂probably accumulated in Earth's oceans -- to significant levels, according to our data -- well before doing so in the atmosphere."

"Now that we know when and where O₂began to build up, the next question is why" says ASU President's Professor and co-author Anbar. "We think that bacteria that produce O₂were thriving in the oceans long before O₂began to build up in the atmosphere. What changed to cause that build-up? That's what we're working on next."