Earth's geodynamic evolution constrained by 182 W in Archean seawater.
Andrea MundlSebastian ViehmannJonas TuschM BauF KurzweilCarsten MünkerPublished in: Nature communications (2022)
Radiogenic isotope systems are important geochemical tools to unravel geodynamic processes on Earth. Applied to ancient marine chemical sediments such as banded iron formations, the short-lived 182 Hf- 182 W isotope system can serve as key instrument to decipher Earth's geodynamic evolution. Here we show high-precision 182 W isotope data of the 2.7 Ga old banded iron formation from the Temagami Greenstone Belt, NE Canada, that reveal distinct 182 W differences in alternating Si-rich (7.9 ppm enrichment) and Fe-rich (5.3 ppm enrichment) bands reflecting variable flux of W from continental and hydrothermal mantle sources into ambient seawater, respectively. Greater 182 W excesses in Si-rich layers relative to associated shales (5.9 ppm enrichment), representing regional upper continental crust composition, suggest that the Si-rich bands record the global rather than the local seawater 182 W signature. The distinct intra-band differences highlight the potential of 182 W isotope signatures in banded iron formations to simultaneously track the evolution of crust and upper mantle through deep time.
Keyphrases
- heavy metals
- gas chromatography
- molecularly imprinted
- iron deficiency
- genome wide
- air pollution
- pet ct
- mass spectrometry
- drinking water
- electronic health record
- particulate matter
- risk assessment
- big data
- health risk
- machine learning
- deep learning
- dna methylation
- sewage sludge
- tandem mass spectrometry
- climate change
- acute heart failure
- organic matter
- simultaneous determination