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Benthic Dissolved Silicon and Iron Cycling at Glaciated Patagonian Fjord Heads

Glacier meltwater supplies silicon (Si) and iron (Fe) sourced from weathered bedrock to downstream ecosystems. However, the extent to which these nutrients reach the ocean is regulated by the nature of the benthic cycling of dissolved Si and Fe within fjord systems, given the rapid deposition of rea...

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Detalles Bibliográficos
Autores principales: Ng, Hong Chin, Hawkings, Jon R., Bertrand, Sebastien, Summers, Brent A., Sieber, Matthias, Conway, Tim M., Freitas, Felipe S., Ward, James P. J., Pryer, Helena V., Wadham, Jemma L., Arndt, Sandra, Hendry, Katharine R.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: John Wiley and Sons Inc. 2022
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9786927/
https://www.ncbi.nlm.nih.gov/pubmed/36582664
http://dx.doi.org/10.1029/2022GB007493
Descripción
Sumario:Glacier meltwater supplies silicon (Si) and iron (Fe) sourced from weathered bedrock to downstream ecosystems. However, the extent to which these nutrients reach the ocean is regulated by the nature of the benthic cycling of dissolved Si and Fe within fjord systems, given the rapid deposition of reactive particulate fractions at fjord heads. Here, we examine the benthic cycling of the two nutrients at four Patagonian fjord heads through geochemical analyses of sediment pore waters, including Si and Fe isotopes (δ(30)Si and δ(56)Fe), and reaction‐transport modeling for Si. A high diffusive flux of dissolved Fe from the fjord sediments (up to 0.02 mmol m(−2) day(−1)) compared to open ocean sediments (typically <0.001 mmol m(−2) day(−1)) is supported by both reductive and non‐reductive dissolution of glacially‐sourced reactive Fe phases, as reflected by the range of pore water δ(56)Fe (−2.7 to +0.8‰). In contrast, the diffusive flux of dissolved Si from the fjord sediments (0.02–0.05 mmol m(−2) day(−1)) is relatively low (typical ocean values are >0.1 mmol m(−2) day(−1)). High pore water δ(30)Si (up to +3.3‰) observed near the Fe(II)‐Fe(III) redox boundary is likely associated with the removal of dissolved Si by Fe(III) mineral phases, which, together with high sedimentation rates, contribute to the low diffusive flux of Si at the sampled sites. Our results suggest that early diagenesis promotes the release of dissolved Fe, yet suppresses the release of dissolved Si at glaciated fjord heads, which has significant implications for understanding the downstream transport of these nutrients along fjord systems.