Apatite and magnetite as probes into dissimilatory iron reduction in banded iron formations

IF 3.6 2区地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS

Chemical Geology Pub Date : 2025-02-06 DOI:10.1016/j.chemgeo.2025.122676

Tianyang Hu , Leslie J. Robbins , Kurt O. Konhauser , Lei Liu , Brendan A. Bishop , Guoxiang Chi , Lijuan Xu

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Abstract

Banded iron formations (BIFs) are ancient sedimentary deposits that provide critical insights into the evolution of Earth's early atmosphere, hydrosphere, and biosphere. This study focuses on the Ouyang BIF in the North China Craton (NCC), highlighting the substantial impact of dissimilatory Fe(III) reduction (DIR) on both the remobilization of iron from the primary iron precipitates and subsequent authigenic mineralization during diagenesis. This biological process is manifested in the light iron isotopes in magnetite (δ⁵⁶Fe values down to −2.1 ± 0.02 ‰) and distinct geochemical signatures in associated apatite. Specifically, the elevated Mn/U ratios (ranging from 467 to 1210) in apatite indicates redox cycling, while elevated concentrations of Sr (ranging from 15,453 to 20,466 ppm), and OH (33 % to 58 % in molar) in apatite are characteristic of biomineralization processes during BIF formation. The relationship observed between Sm/Nd ratios (and Nd isotopes) in apatite and δ⁵⁶Fe values in magnetite further suggests that iron was sourced to the Wuyang BIFs from both hydrothermal fluids and a benthic iron flux. Notably, the benthic Fe flux likely resulted from the DIR of ferric oxyhydroxide minerals in nearshore sediments, highlighting the essential role of continental iron and DIR in transporting Fe from the continents to BIF depositional centers. This study underscores the critical influence of microbial activity in iron cycling within ancient oceans. It further showcases how DIR was recorded by apatite and magnetite, offering insights into past DIR bacteria during BIF deposition.

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磷灰石和磁铁矿作为带状铁地层中异化铁还原的探针

带状铁地层（BIFs）是古老的沉积矿床，为了解地球早期大气、水圈和生物圈的演化提供了重要的见解。本文以华北克拉通欧阳BIF为研究对象，探讨了成岩过程中异化铁（III）还原（DIR）对原生铁沉淀中铁的再活化和自生成矿作用的重要影响。这一生物过程表现在磁铁矿的轻铁同位素（δ56Fe值低至- 2.1±0.02‰）和伴生磷灰石的明显地球化学特征上。具体来说，磷灰石中Mn/U比值的升高（范围从467到1210）表明了氧化还原循环，而磷灰石中Sr浓度的升高（范围从15,453到20,466 ppm）和OH浓度的升高（摩尔浓度为33%到58%）是生物矿化过程中BIF形成的特征。磷灰石中Sm/Nd比值（和Nd同位素）与磁铁矿中δ56Fe值的关系进一步表明，铁来源于热液流体和底底铁通量。值得注意的是，底栖铁通量可能是由近岸沉积物中氧化铁矿物的DIR引起的，这突出了大陆铁和DIR在将铁从大陆输送到BIF沉积中心中的重要作用。这项研究强调了微生物活动对古代海洋铁循环的关键影响。它进一步展示了磷灰石和磁铁矿如何记录DIR，为BIF沉积期间过去的DIR细菌提供了见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Chemical Geology 地学-地球化学与地球物理

CiteScore

7.20

自引率

10.30%

发文量

374

审稿时长

3.6 months

期刊介绍： Chemical Geology is an international journal that publishes original research papers on isotopic and elemental geochemistry, geochronology and cosmochemistry. The Journal focuses on chemical processes in igneous, metamorphic, and sedimentary petrology, low- and high-temperature aqueous solutions, biogeochemistry, the environment and cosmochemistry. Papers that are field, experimentally, or computationally based are appropriate if they are of broad international interest. The Journal generally does not publish papers that are primarily of regional or local interest, or which are primarily focused on remediation and applied geochemistry. The Journal also welcomes innovative papers dealing with significant analytical advances that are of wide interest in the community and extend significantly beyond the scope of what would be included in the methods section of a standard research paper.