Published in
Nature Research, Nature Communications, 1(6), 2015
DOI: 10.1038/ncomms10157
Links
- ORCID
- ORCID
- Nature Research | PDF
- ORCID
- [research-repository.st-andrews.ac.uk] | PDF
- [research-information.bristol.ac.uk] | PDF
- [research-information.bristol.ac.uk] | PDF
- [eprints.bbk.ac.uk] | PDF
- [eprints.whiterose.ac.uk] | PDF
- [discovery.ucl.ac.uk] | PDF
- [europepmc.org] | PDF
- [www.ncbi.nlm.nih.gov] | PDF
Tools
Selenium isotope evidence for progressive oxidation of the Neoproterozoic biosphere
,
Eva E. Stüeken,
Tim Elliott,
Simon W. Poulton ,
Carol M. Dehler,
Don E. Canfield,
David C. Catling
Full text: Download
Abstract
AbstractNeoproterozoic (1,000–542 Myr ago) Earth experienced profound environmental change, including ‘snowball’ glaciations, oxygenation and the appearance of animals. However, an integrated understanding of these events remains elusive, partly because proxies that track subtle oceanic or atmospheric redox trends are lacking. Here we utilize selenium (Se) isotopes as a tracer of Earth redox conditions. We find temporal trends towards lower δ82/76Se values in shales before and after all Neoproterozoic glaciations, which we interpret as incomplete reduction of Se oxyanions. Trends suggest that deep-ocean Se oxyanion concentrations increased because of progressive atmospheric and deep-ocean oxidation. Immediately after the Marinoan glaciation, higher δ82/76Se values superpose the general decline. This may indicate less oxic conditions with lower availability of oxyanions or increased bioproductivity along continental margins that captured heavy seawater δ82/76Se into buried organics. Overall, increased ocean oxidation and atmospheric O2 extended over at least 100 million years, setting the stage for early animal evolution.