Summary
Rare earth elements (REE) and transition and post-transition metals (TM) are essential to modern life, yet we know little about how they concentrate at Earth’s surface, especially on the seafloor, which holds vast reserves. The DEEP-SEE project will shift paradigms on marine metal deposits from chemical composition and resource inventories to a holistic view based on atomic-scale observations and modeling. This research will determine geochemical processes that give rise to some of the highest metal partitionings in supergene ores. First, crystal chemistry of 3+ REE in biogenic vs. authigenic sedimentary apatite is proposed as a new proxy for the paleoceanographic enrichment setting with the potential to become an indicator for future exploration sites. Second, crystal chemistry of 3+ REE will elucidate the scavenging history of Fe-Mn crusts and corresponding evolution of seawater REE as recorded in growth layers over millions of years. Third, investigation of the redox chemistry and mineralogy of Fe-Mn crusts and nodules will explain how the redox-sensitive metals Co, Ce, Tl, and Pt are enriched from 109 to 106 times relative to seawater. To date, these processes have been impossible to interrogate because of analytical challenges posed by the multi-elemental composition and mineralogical heterogeneity of seafloor deposits. A promising approach for tackling these challenges is new micro-X-ray emission spectroscopy using a unique high-luminosity compact XES spectrometer at the European Synchrotron Radiation Facility. Installation of the spectrometer on a microfocus beamline under construction on the new 4th generation ESRF X-ray source will provide a momentous gain of at least 100 in detection limit and unprecedented sensitivity and precision in the analysis of REE and TM. More broadly, the research will show how new knowledge about Earth processes can be obtained with a fresh look at individual trace elements previously inaccessible by crystal chemical study.
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Web resources: | https://cordis.europa.eu/project/id/101052913 |
Start date: | 01-04-2023 |
End date: | 31-03-2028 |
Total budget - Public funding: | 2 370 431,25 Euro - 2 370 431,00 Euro |
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Original description
Rare earth elements (REE) and transition and post-transition metals (TM) are essential to modern life, yet we know little about how they concentrate at Earth’s surface, especially on the seafloor, which holds vast reserves. The DEEP-SEE project will shift paradigms on marine metal deposits from chemical composition and resource inventories to a holistic view based on atomic-scale observations and modeling. This research will determine geochemical processes that give rise to some of the highest metal partitionings in supergene ores. First, crystal chemistry of 3+ REE in biogenic vs. authigenic sedimentary apatite is proposed as a new proxy for the paleoceanographic enrichment setting with the potential to become an indicator for future exploration sites. Second, crystal chemistry of 3+ REE will elucidate the scavenging history of Fe-Mn crusts and corresponding evolution of seawater REE as recorded in growth layers over millions of years. Third, investigation of the redox chemistry and mineralogy of Fe-Mn crusts and nodules will explain how the redox-sensitive metals Co, Ce, Tl, and Pt are enriched from 109 to 106 times relative to seawater. To date, these processes have been impossible to interrogate because of analytical challenges posed by the multi-elemental composition and mineralogical heterogeneity of seafloor deposits. A promising approach for tackling these challenges is new micro-X-ray emission spectroscopy using a unique high-luminosity compact XES spectrometer at the European Synchrotron Radiation Facility. Installation of the spectrometer on a microfocus beamline under construction on the new 4th generation ESRF X-ray source will provide a momentous gain of at least 100 in detection limit and unprecedented sensitivity and precision in the analysis of REE and TM. More broadly, the research will show how new knowledge about Earth processes can be obtained with a fresh look at individual trace elements previously inaccessible by crystal chemical study.Status
SIGNEDCall topic
ERC-2021-ADGUpdate Date
09-02-2023
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