Marine eutrophication within the Tarim Platform in sync with Middle to Late Ordovician climatic cooling

Junpeng Zhang, Wenjie Li, Xiang Fang, Xuejin Wu, Chao Li, Yuandong Zhang
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Abstract

Previous work has proposed climatic cooling and atmosphere-ocean oxygenation as potential triggers for the Great Ordovician Biodiversification Event, with the suggestion of better oxygenated oceans during the Middle to Late Ordovician. However, recent studies have argued for spatial and temporal heterogeneity in marine redox state on several continents. Here we investigated a black-shale succession accumulated within the Tarim Platform via a combination of geochemical proxies to address these debates. Negative shifts in bulk nitrogen isotopes and synchronous increases in excess P suggest moderate-high marine primary production coinciding with the development of bottom-water anoxia, as indicated by enrichments in highly reactive iron and modest concentrations of redox-sensitive trace metals (Mo, U). Moreover, the occurrence of black shale correlates well with equivalent successions formed in deep-water marginal basins along several continents, including South China, North China, Laurentia and Baltica. This may suggest an expansion of marine anoxia in low-latitude zones of the late Darriwilian to early Sandbian oceans, probably as a result of enhanced upwelling in sync with climatic cooling. The extent and ultimate cause of marine anoxia requires further quantifying constraints at a global scale, which will enable potential links between global oceanic redox conditions and concurrent biotic changes to be evaluated in more detail. Thematic collection: This article is part of the Chemical Evolution of the Mid-Paleozoic Earth System and Biotic Response collection available at: https://www.lyellcollection.org/topic/collections/chemical-evolution-of-the-mid-paleozoic-earth-system Supplementary material: https://doi.org/10.6084/m9.figshare.c.7036552
塔里木地台上的海洋富营养化与中奥陶纪至晚奥陶纪的气候变冷同步
以往的研究提出,气候变冷和大气-海洋含氧量增加是奥陶纪生物大分化事件的潜在触发因素,并认为奥陶纪中、晚期海洋含氧量增加。然而,最近的研究表明,几大洲的海洋氧化还原状态存在时空异质性。在此,我们结合地球化学代用指标,对塔里木地台上堆积的黑页岩演替进行了研究,以解决这些争论。大量氮同位素的负迁移和过量磷的同步增加表明,海洋初级生产力处于中等水平,与底层水缺氧的发展相吻合,高活性铁的富集和对氧化还原敏感的痕量金属(钼、铀)的适度富集也表明了这一点。此外,黑色页岩的出现与华南、华北、劳伦西亚和波罗的海等几大洲深水边缘盆地中形成的等效演替密切相关。这可能表明,海洋缺氧现象在达里维利晚期至沙比安早期海洋的低纬度地区有所扩大,这可能是与气候变冷同步的上升流增强的结果。海洋缺氧的范围和最终原因需要在全球范围内进一步量化制约因素,这样才能更详细地评估全球海洋氧化还原条件与同时发生的生物变化之间的潜在联系。 专题集:本文是中古生代地球系统化学演化与生物响应文集的一部分,可在以下网址查阅: https://www.lyellcollection.org/topic/collections/chemical-evolution-of-the-mid-paleozoic-earth-system 补充材料: https://doi.org/10.6084/m9.figshare.c.7036552
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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