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Global marine redox changes drove the rise and fall of the Ediacara biota
Author(s) -
Zhang Feifei,
Xiao Shuhai,
Romaniello Stephen J.,
Hardisty Dalton,
Li Chao,
Melezhik Victor,
Pokrovsky Boris,
Cheng Meng,
Shi Wei,
Lenton Timothy M.,
Anbar Ariel D.
Publication year - 2019
Publication title -
geobiology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.859
H-Index - 72
eISSN - 1472-4669
pISSN - 1472-4677
DOI - 10.1111/gbi.12359
Subject(s) - biota , anoxic waters , oceanography , geology , ocean chemistry , seafloor spreading , paleontology , ecology , seawater , biology
Abstract The role of O 2 in the evolution of early animals, as represented by some members of the Ediacara biota, has been heavily debated because current geochemical evidence paints a conflicting picture regarding global marine O 2 levels during key intervals of the rise and fall of the Ediacara biota. Fossil evidence indicates that the diversification the Ediacara biota occurred during or shortly after the Ediacaran Shuram negative C‐isotope Excursion (SE), which is often interpreted to reflect ocean oxygenation. However, there is conflicting evidence regarding ocean oxygen levels during the SE and the middle Ediacaran Period. To help resolve this debate, we examined U isotope variations (δ 238 U) in three carbonate sections from South China, Siberia, and USA that record the SE. The δ 238 U data from all three sections are in excellent agreement and reveal the largest positive shift in δ 238 U ever reported in the geologic record (from ~ −0.74‰ to ~ −0.26‰). Quantitative modeling of these data suggests that the global ocean switched from a largely anoxic state (26%–100% of the seafloor overlain by anoxic waters) to near‐modern levels of ocean oxygenation during the SE. This episode of ocean oxygenation is broadly coincident with the rise of the Ediacara biota. Following this initial radiation, the Ediacara biota persisted until the terminal Ediacaran period, when recently published U isotope data indicate a return to more widespread ocean anoxia. Taken together, it appears that global marine redox changes drove the rise and fall of the Ediacara biota.