Revolutionary Dating Method Illuminates the Oxygenation of Ancient Seas

Revolutionary Dating Method Illuminates the Oxygenation of Ancient Seas
by Hugo Ritmico
Madrid, Spain (SPX) Apr 05, 2024

In a groundbreaking advancement, researchers at Hebrew University have employed dolomite U-Pb geochronology to chart the oxygen levels in ancient marine environments. This innovative approach has unearthed variances in the U-Pb ratios of dolomite samples, establishing a novel method for deducing the oxygen content of ancient oceans. The analysis highlights a pronounced increase in marine oxygenation during the Late Paleozoic era, around 400 million years ago. This era postdates the advent of animal life by hundreds of millions of years, indicating that the earliest animals inhabited predominantly oxygen-deficient oceans. The insights gained from this study not only refine our comprehension of the interplay between ecological systems and the development of complex life but also aid in the search for extraterrestrial life by providing a framework for interpreting atmospheric compositions of exoplanets through advanced space telescopes.

The work of Dr. Uri Ryb, Dr. Michal Ben-Israel, and their team at the Institute of Earth Sciences marks a significant stride in Earth sciences. Their paper, featured in Nature Communications, pioneers the use of uranium and lead measurements in dolomite rocks spanning the last 1.2 billion years to trace the escalation of oxygen in ancient seas. This method overcomes the limitations of previous techniques that relied on the analysis of 'redox sensitive' elements in sedimentary rocks, which are prone to alteration over geological timescales.

The findings underscore a notable surge in ocean oxygenation during the Late Paleozoic era, corroborating other indicators of increased oxygen levels during this period. This evidence supports the notion that the evolutionary journey of animals unfolded in environments with limited oxygen availability and suggests that evolutionary processes may have influenced oceanic oxygen levels.

Dr. Ryb emphasizes the broader implications of their research, noting its potential to enhance our understanding of the conditions conducive to the emergence and sustenance of complex life, both on early Earth and potentially on other planets. This study lays the groundwork for future explorations into the atmospheric properties of exoplanets, offering new perspectives on the prerequisites for complex life beyond our planet.

Research Report:Late Paleozoic oxygenation of marine environments supported by dolomite U-Pb dating