Low content of highly reactive iron in sediments from Prydz Bay and the adjacent Southern Ocean: Controlling factors and implications for sedimentary organic carbon preservation

Examining iron (Fe) speciation in marine sediments is critical to understand Fe and carbon biogeochemical cycling in polar regions. In this study, we investigated the speciation of Fe in sediments from Prydz Bay and the adjacent Southern Ocean, and examined the factors controlling Fe speciation and...

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Bibliographic Details
Published in:Frontiers in Marine Science
Main Authors: Huang, Wenhao, Guo, Xiaoze, Zhao, Jun, Li, Dong, Hu, Ji, Zhang, Haifeng, Zhang, Cai, Han, Zhengbing, Sun, Weiping, Sun, Yongge, Pan, Jianming
Other Authors: National Natural Science Foundation of China
Format: Article in Journal/Newspaper
Language:unknown
Published: Frontiers Media SA 2023
Subjects:
Ocean Engineering
Water Science and Technology
Aquatic Science
Global and Planetary Change
Oceanography
Prydz Bay
Southern Ocean
Online Access:http://dx.doi.org/10.3389/fmars.2023.1142061
https://www.frontiersin.org/articles/10.3389/fmars.2023.1142061/full
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Summary:Examining iron (Fe) speciation in marine sediments is critical to understand Fe and carbon biogeochemical cycling in polar regions. In this study, we investigated the speciation of Fe in sediments from Prydz Bay and the adjacent Southern Ocean, and examined the factors controlling Fe speciation and its relationship with total organic carbon (TOC). Our results reveal that unreactive silicate Fe (Fe U ) is the dominant pool of total Fe (Fe T ), followed by poorly reactive sheet silicate Fe (Fe PRS ), reducible crystalline Fe oxides (Fe ox2 ), easily reducible amorphous/poorly crystalline Fe oxides (Fe ox1 ), and magnetite (Fe mag ), with carbonate-associated ferrous Fe (Fe carb ) being the smallest pool. The highly reactive Fe (Fe HR )/Fe T ratios (0.13 ± 0.06) in our study area are among the lowest end-member globally, primarily due to weak bedrock weathering and slow glacier melting. The Fe ox1 /Fe T ratios are similar to those in continental shelf and marginal seas containing highly weathered materials, while the Fe ox2 /Fe T ratios are significantly lower. This result implicates that low temperature inhibits the aging of iceberg melting-sourced Fe ox1 potentially, and accordingly the regulation of weathering on the Fe HR /Fe T ratio is mainly reflected in Fe ox2 /Fe T ratio. There are no significant correlations between TOC and Fe HR , Fe carb , Fe ox1 or Fe ox2 in the research region. Four distinct patterns of TOC/Fe HR ratio can be discerned by summarizing the global data set: (a) high TOC/Fe HR ratios (> 2.5) are likely the result of high marine primary productivity and low chemically weathered source materials; (b) low TOC/Fe HR ratios (< 0.6) are caused by high rates of Fe HR inputs and OC remineralization; (c) mid-range TOC/Fe HR ratios (0.6 – 2.5) typical of most river particulates and marginal sea sediments indicate the same Fe HR and OC sources and/or interactions between each other; (d) both low TOC and Fe HR content is the result of low marine primary productivity and weak chemical ...

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