古新世海底的快照:3.43-3.35 Ga Strelley Pool 绿泥石-卵石砾岩沉积、硅化和热液绿泥石-磷灰石沉淀侵蚀的证据

IF 3.2 2区 地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY Precambrian Research Pub Date : 2024-08-02 DOI:10.1016/j.precamres.2024.107531
B. Rasmussen , J.R. Muhling , A. Sadekov
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引用次数: 0

摘要

在澳大利亚皮尔巴拉克拉通北部以火山为主的古新世序列中,有一些最古老、保存完好的外喷沉积岩(铁砾石和海泡石)。浊积岩含有细粒赤铁矿颗粒,据解释,这些颗粒是光自养生物将喷口产生的铁(aq)经海水氧化后形成的。然而,最近的研究表明,海泡石中的大部分铁最初是以绿泥石等富含铁(II)的硅酸盐沉积而成的,这再次引发了关于早期海洋中铁是如何沉淀的争论。在这里,我们展示了澳大利亚皮尔巴拉克拉通北极穹隆 3.43-3.35 Ga Strelley Pool Formation 基底砾岩中的圆形尘状铁纹石碎屑,这些碎屑含有丰富的纳米绿帘石和磷灰石,在质地、矿物学和化学性质上与澳大利亚哈默斯利组新元古代带状铁地层中的情况几乎相同。赤铁矿的含量微乎其微,而且分布在岩屑边缘,这意味着至少有一部分赤铁矿是在风化过程中形成的。富含绿泥石的碎屑显示出明显的页岩归一化 Eu 正异常、较小的 Y 正异常以及缺乏 La 正异常,这些都是古新世喷出岩的典型特征。富含绿泥石和磷灰石的白垩系鹅卵石与热液黑燧石和硅化长石火山碎屑沉积岩的碎屑同时出现,这表明这里是一个热液活动剧烈的火山活动产地,与下伏的3.43 Ga Panorama地层相一致。我们认为,绿帘石和磷灰石纳米颗粒是在热液喷口流体与缺氧海水混合过程中沉淀下来的,并在海底硅化。白垩岩碎屑的圆形到椭圆形表明,硅胶结物在侵蚀之前已经重结晶,这与含尘白垩岩碎屑中存在的多边形收缩结构相一致。我们的研究结果表明,与最近的观点相反,绿泥石不仅形成于古新世的海水中,而且在沉积、成岩和再沉积过程中也是稳定的。古新世海水中磷灰石纳米颗粒的沉淀和不溶解表明磷酸盐浓度升高,而原生赤铁矿的缺失则与主张阿卡干时期非生物铁沉积作用的模型相一致。
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Snapshot of a Paleoarchean seafloor: Evidence from 3.43-3.35 Ga Strelley Pool chert-pebble conglomerate for deposition, silicification, and erosion of hydrothermal greenalite-apatite precipitates

Some of the oldest, well-preserved exhalative sedimentary rocks (ferruginous cherts and jaspilites) occur in volcanic-dominated Paleoarchean sequences in the northern Pilbara Craton, Australia. Jaspilites contain fine-grained hematite particles that have been interpreted to have formed following seawater oxidation of vent-derived Fe2+(aq) by photoautotrophs. However, recent studies suggest that most of the iron in the jaspilites was originally deposited as Fe(II)-rich silicates such as greenalite, sparking renewed debate about how iron was precipitated in the early oceans. Here we show that rounded clasts of dusty ferruginous chert in basal conglomerates of the 3.43–3.35 Ga Strelley Pool Formation, North Pole Dome, Pilbara Craton, Australia, contain abundant nanoparticles of greenalite and apatite that are texturally, mineralogically and chemically near-identical to occurrences in Neoarchean banded iron formations in the Hamersley Group, Australia. Hematite where present occurs in trace amounts and its distribution along the edges of clasts implies that at least some of the hematite formed during weathering. The greenalite-rich clasts display a pronounced positive shale-normalized Eu anomaly, small positive Y anomaly and lack a positive La anomaly, features typical of Paleoarchean exhalites. The co-occurrence of greenalite- and apatite-rich chert-pebbles with clasts of hydrothermal black chert and silicified felsic volcaniclastic sedimentary rocks points to a volcanically active provenance with vigorous hydrothermal activity, consistent with derivation from the underlying 3.43 Ga Panorama Formation. We argue that the greenalite and apatite nanoparticles precipitated during mixing between hydrothermal vent fluids and anoxic seawater and were silicified on the seafloor. The round to oval shape of the chert clasts indicates that the silica cement had recrystallized prior to erosion, consistent with the presence of polygonal shrinkage structures in the dusty chert clasts. Our findings imply that greenalite, contrary to recent suggestions, not only formed in Paleoarchean seawater, but was also stable during deposition, diagenesis, and resedimentation. The precipitation and non-dissolution of apatite nanoparticles in Paleoarchean seawater points to elevated phosphate concentrations, whereas the absence of primary hematite is consistent with models advocating a role for abiotic iron deposition during the Archean.

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来源期刊
Precambrian Research
Precambrian Research 地学-地球科学综合
CiteScore
7.20
自引率
28.90%
发文量
325
审稿时长
12 months
期刊介绍: Precambrian Research publishes studies on all aspects of the early stages of the composition, structure and evolution of the Earth and its planetary neighbours. With a focus on process-oriented and comparative studies, it covers, but is not restricted to, subjects such as: (1) Chemical, biological, biochemical and cosmochemical evolution; the origin of life; the evolution of the oceans and atmosphere; the early fossil record; palaeobiology; (2) Geochronology and isotope and elemental geochemistry; (3) Precambrian mineral deposits; (4) Geophysical aspects of the early Earth and Precambrian terrains; (5) Nature, formation and evolution of the Precambrian lithosphere and mantle including magmatic, depositional, metamorphic and tectonic processes. In addition, the editors particularly welcome integrated process-oriented studies that involve a combination of the above fields and comparative studies that demonstrate the effect of Precambrian evolution on Phanerozoic earth system processes. Regional and localised studies of Precambrian phenomena are considered appropriate only when the detail and quality allow illustration of a wider process, or when significant gaps in basic knowledge of a particular area can be filled.
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