Xinqian Wang, Chen Zhan, T. Algeo, Jun Shen, Zhanhong Liu
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Carbon-isotope (\n \n \n δ\n \n \n 13\n C\n org\n ) profiles show that the Guanyinqiao Bed (recording peak Hirnantian glaciation) thins and is less completely preserved at sites on the flanks of the Hunan-Hubei Arch than in deeper-water areas to the SW and NE, reflecting bathymetric influences. Watermass salinities were mainly marine at Shuanghe and brackish at the other four study sites, with little variation between Interval I (pre-glaciation), Interval II (Hirnantian glaciation), and Interval III (post-glaciation). Redox proxies document mainly euxinia at Shuanghe and Wangjiawan and suboxia at the other sites during Interval I, with shifts toward more reducing (mostly euxinic) conditions at most sites during Intervals II and III, which shows that all study sections were deep enough to remain below the redoxcline during the glacio-eustatic lowstand. Two features of the Shuanghe section mark it as being unusual: it alone exhibits fully marine salinities, implying greater proximity to the open ocean than for the other four sites, and it exhibits an especially large shift toward more reducing conditions during Interval III (i.e., the post-Hirnantian transgression), implying greater water depths. These features are difficult to reconcile with the standard palaeogeographic model for the Ordovician-Silurian South China Craton, which is characterized by a geographically enclosed and restricted IYS and a more-open OYS, arguing instead for the SW end of the IYS having been connected to the global ocean and the OYS having been a restricted oceanic cul-de-sac. A review of sedimentologic and facies data for the IYS region suggests that our re-interpretation of the Ordovician-Silurian palaeogeography of the South China Craton is viable, although further vetting of this hypothesis will be needed.\n \n \n Thematic collection:\n This article is part of the Chemical Evolution of the Mid-Paleozoic Earth System and Biotic Response collection available at:\n https://www.lyellcollection.org/topic/collections/chemical-evolution-of-the-mid-paleozoic-earth-system\n \n \n Supplementary material:\n https://doi.org/10.6084/m9.figshare.c.7170648\n","PeriodicalId":507891,"journal":{"name":"Journal of the Geological Society","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2024-04-10","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":"{\"title\":\"Watermass architecture of the Ordovician-Silurian Yangtze Sea (South China) and its palaeogeographic implications\",\"authors\":\"Xinqian Wang, Chen Zhan, T. 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Carbon-isotope (\\n \\n \\n δ\\n \\n \\n 13\\n C\\n org\\n ) profiles show that the Guanyinqiao Bed (recording peak Hirnantian glaciation) thins and is less completely preserved at sites on the flanks of the Hunan-Hubei Arch than in deeper-water areas to the SW and NE, reflecting bathymetric influences. Watermass salinities were mainly marine at Shuanghe and brackish at the other four study sites, with little variation between Interval I (pre-glaciation), Interval II (Hirnantian glaciation), and Interval III (post-glaciation). Redox proxies document mainly euxinia at Shuanghe and Wangjiawan and suboxia at the other sites during Interval I, with shifts toward more reducing (mostly euxinic) conditions at most sites during Intervals II and III, which shows that all study sections were deep enough to remain below the redoxcline during the glacio-eustatic lowstand. Two features of the Shuanghe section mark it as being unusual: it alone exhibits fully marine salinities, implying greater proximity to the open ocean than for the other four sites, and it exhibits an especially large shift toward more reducing conditions during Interval III (i.e., the post-Hirnantian transgression), implying greater water depths. These features are difficult to reconcile with the standard palaeogeographic model for the Ordovician-Silurian South China Craton, which is characterized by a geographically enclosed and restricted IYS and a more-open OYS, arguing instead for the SW end of the IYS having been connected to the global ocean and the OYS having been a restricted oceanic cul-de-sac. 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引用次数: 1
摘要
在晚奥陶世希尔南天冰期,华南克拉通地区经历了气候、温差和环境条件的巨大变化,但这些变化对长江海水体结构的影响迄今尚未得到全面评估。在此,我们基于五个上奥陶世-下志留纪页岩演替重建了长江海的盐度-氧化还原结构,这五个页岩演替代表了一个横向剖面,从长江内海(IYS;双河剖面)的深水区穿过湘沪拱浅水区(彭野、焦野和祁辽剖面)到相对深水的长江外海(OYS;王家湾剖面)。碳同位素(δ 13 C org)剖面显示,与西南和东北深水区相比,湘湖北拱两侧的观音桥海床(记录了希南特冰川作用的高峰期)变薄,且保存不够完整,这反映了水深的影响。双河的水体盐度主要是海洋性的,而其他四个研究地点的水体盐度则是咸的,在第一期(冰期前)、第二期(平南天冰期)和第三期(冰期后)之间几乎没有变化。氧化还原代用指标表明,在第一期期间,双河和王家湾主要处于氧化还原状态,其他地点则处于亚氧化状态,而在第二期和第三期期间,大多数地点的氧化还原状态(主要是氧化还原状态)有所改变,这表明在冰期-极低位期间,所有研究断面的深度足以保持在氧化还原线以下。双河断面有两个不同寻常的特征:与其他四个地点相比,双河断面显示出完全的海洋盐度,这意味着双河断面更接近于公海;双河断面在第三期(即后希尔南天横断期)向更高的还原条件转变的幅度特别大,这意味着双河断面的水深更大。这些特征很难与奥陶纪-志留纪华南克拉通的标准古地理模型相协调,后者的特征是一个地理上封闭和受限的IYS和一个更开放的OYS,而IYS的西南端与全球海洋相连,OYS则是一个受限的大洋死胡同。对IYS地区沉积学和岩相学数据的回顾表明,我们对华南克拉通奥陶纪-志留纪古地理的重新解释是可行的,尽管这一假说还需要进一步验证。 专题文集: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,可从以下网址获取: 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.7170648
Watermass architecture of the Ordovician-Silurian Yangtze Sea (South China) and its palaeogeographic implications
During the Late Ordovician Hirnantian Ice Age, the South China Craton experienced large changes in climate, eustasy, and environmental conditions, but their impact on the watermass architecture of the Yangtze Sea has not been thoroughly evaluated to date. Here, we reconstruct the salinity-redox structure of the Yangtze Sea based on five Upper Ordovician-lower Silurian shale successions representing a lateral transect, from a deep-water area of the Inner Yangtze Sea (IYS; Shuanghe section) across the shallow Hunan-Hubei Arch (Pengye, Jiaoye, and Qiliao sections) to the relatively deep-water Outer Yangtze Sea (OYS; Wangjiawan section). Carbon-isotope (
δ
13
C
org
) profiles show that the Guanyinqiao Bed (recording peak Hirnantian glaciation) thins and is less completely preserved at sites on the flanks of the Hunan-Hubei Arch than in deeper-water areas to the SW and NE, reflecting bathymetric influences. Watermass salinities were mainly marine at Shuanghe and brackish at the other four study sites, with little variation between Interval I (pre-glaciation), Interval II (Hirnantian glaciation), and Interval III (post-glaciation). Redox proxies document mainly euxinia at Shuanghe and Wangjiawan and suboxia at the other sites during Interval I, with shifts toward more reducing (mostly euxinic) conditions at most sites during Intervals II and III, which shows that all study sections were deep enough to remain below the redoxcline during the glacio-eustatic lowstand. Two features of the Shuanghe section mark it as being unusual: it alone exhibits fully marine salinities, implying greater proximity to the open ocean than for the other four sites, and it exhibits an especially large shift toward more reducing conditions during Interval III (i.e., the post-Hirnantian transgression), implying greater water depths. These features are difficult to reconcile with the standard palaeogeographic model for the Ordovician-Silurian South China Craton, which is characterized by a geographically enclosed and restricted IYS and a more-open OYS, arguing instead for the SW end of the IYS having been connected to the global ocean and the OYS having been a restricted oceanic cul-de-sac. A review of sedimentologic and facies data for the IYS region suggests that our re-interpretation of the Ordovician-Silurian palaeogeography of the South China Craton is viable, although further vetting of this hypothesis will be needed.
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.7170648