Morphology‐Dependent Magnetic Properties in Shallow‐Water Ferromanganese Concretions

Morphology‐Dependent Magnetic Properties in Shallow‐Water Ferromanganese Concretions

Ferromanganese concretions commonly occur in shallow‐water coastal regions worldwide. In the Baltic Sea, they can record information about past and present underwater environments and could be a potential source for critical raw materials. We report on their microstructural characteristics and magne...

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Published in:Geochemistry, geophysics, geosystems : G3 Vol. 25; no. 5
Main Authors: Wasiljeff, Joonas, Salminen, Johanna M., Roberts, Andrew P., Hu, Pengxiang, Brown, Maxwell, Kuva, Jukka, Lukkari, Sari, Jolis, Ester M., Heinsalu, Atko, Hong, Wei‐Li, Lepland, Aivo, Suuroja, Sten, Parkkonen, Joni, Virtasalo, Joonas J.
Format: Journal Article
Language:English
Published: Washington John Wiley & Sons, Inc 01-05-2024
Wiley
Subjects:
Baltic Sea
Coastal zone
Computed tomography
Concretions
Diagenesis
Electron microscopy
eutrophication
Fe-Mn concretion
Fluorescence
hypoxia
Magnetic properties
magnetotactic bacteria
Mineralization
Raw materials
Sedimentary structures
shelf sea
Tomography
Baltic Sea
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Summary:Ferromanganese concretions commonly occur in shallow‐water coastal regions worldwide. In the Baltic Sea, they can record information about past and present underwater environments and could be a potential source for critical raw materials. We report on their microstructural characteristics and magnetic properties and link them to their formation mechanisms and environmental significance. Microstructural investigations from nano‐ and micro‐computed tomography, electron microscopy, and micro‐X‐ray fluorescence elemental mapping reveal diverse growth patterns within concretions of different morphologies. Alternating Fe‐ and Mn‐rich growth bands indicate fluctuating redox conditions during formation. Bullet‐shaped magnetofossils, produced by magnetotactic bacteria, are present, which suggests the influence of bacterial activity on concretion formation. Spheroidal concretions, which occur in deeper and more tranquil environments, have enhanced microbial biomineralization and magnetofossil preservation. Conversely, crusts and discoidal concretions from shallower and more energetic environments contain fewer magnetofossils and have a greater detrital content. Our results provide insights into concretion formation mechanisms and highlight the importance of diagenetic processes, oxygen availability, and bacterial activity in the Baltic Sea. Key Points Magnetic minerals within shallow water Fe‐Mn concretions can provide valuable environmental information about their formation Magnetic properties are linked to specific growth patterns in Baltic Sea Fe‐Mn concretions Spheroidal and crust/discoidal concretions are dominated by biogenic and pedogenic magnetic phases, respectively
ISSN:1525-2027
1525-2027
DOI:10.1029/2023GC011366