Transient and stepwise ocean oxygenation during the late Ediacaran Shuram Excursion: Insights from carbonate δ238U of northwestern Mexico.

• We present new δ238U data for the entire Shuram Excursion from Sonora, NW Mexico. • Our δ238U data show a delayed positive shift relative to the negative δ13C carb excursion. • Our δ238U data constrain the duration of oxygenation event during Shuram Excursion. • A two-step oxidation model provides new insight into the origin of Shuram Excursion. The Ediacaran Shuram Excursion (SE) was a key episode in the history of atmospheric and oceanic oxygenation that has also been linked to contemporaneous bioevolutionary events. However, key aspects of the redox state of Ediacaran oceans during the SE remain in doubt. Here, the uranium isotope compositions (δ238U) of marine carbonates from Sonora, northwestern Mexico were measured to investigate ocean oxygenation during the SE. We found that the SE in Sonora is characterized by a shift toward higher δ238U values (from −0.7‰ to −0.3‰), consistent with a major oxygenation event that has now been documented in widely separated coeval upper Ediacaran sections including the Doushantuo Formation in South China, the Bol'shoy Patom Formation in Siberia, and the Johnnie Formation in California. In the Sonora Succession, this δ238U shift exhibits a ~0.8-Myr lag relative to the δ13C carb excursion that defines the SE. To account for these observations, we propose a two-step oceanic oxygenation model for the SE: (1) initial oxidation of an aqueous reductant (e.g., dissolved organic carbon) that resulted only in a shift of δ13C carb (from +5‰ to −3‰); and (2) subsequent oxidation of methane or particulate organic matter that caused a continuation of the negative shift in δ13C carb (from −3‰ to −12‰) as well as a positive excursion of δ238U due to progressive oceanic oxygenation. This transient period of enhanced oceanic oxygenation of the late Ediacaran ocean, which may have promoted the evolution of early metazoans, terminated after ~5.0 to 6.5 Myr. [ABSTRACT FROM AUTHOR]