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北钙质阿尔卑斯山脉中部富盐与贫盐构造情景:对哈尔施塔特相及早期阿尔卑斯构造演化的影响(奥地利东阿尔卑斯山脉)

Salt-rich versus salt-poor structural scenarios in the central Northern Calcareous Alps: implications for the Hallstatt facies and early Alpine tectonic evolution (Eastern Alps, Austria).

作者信息

Fernandez Oscar, Ortner Hugo, Sanders Diethard, Grasemann Bernhard, Leitner Thomas

机构信息

Department of Geology, University of Vienna, Josef-Holaubek-Platz 2 (UZA II), 1090 Vienna, Austria.

Department of Geology, University of Innsbruck, Innrain 52f, 6020 Innsbruck, Austria.

出版信息

Int J Earth Sci. 2024;113(2):245-283. doi: 10.1007/s00531-023-02377-4. Epub 2024 Jan 26.

DOI:10.1007/s00531-023-02377-4
PMID:38500652
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10944420/
Abstract

One of the most remarkable features of the central Northern Calcareous Alps (Eastern Alps, Austria) is the widespread presence of Upper Triassic deep-water carbonates (the Hallstatt facies) and Permo-Triassic evaporites resting on deep-water Middle Jurassic strata and their underlying Upper Triassic shallow-water carbonate platform successions. The Hallstatt facies and accompanying evaporites have been classically interpreted to originate either from a location south of the time-equivalent carbonate platforms, or to have been deposited in deeper water seaways within the broad platform domain. To date, this dispute has been addressed mostly through the analysis of Triassic and Jurassic facies distribution in map view, which, however, is subject to some degree of ambiguity and subjectivity. In this contribution we present, for the first time, sequentially restored regional cross-sections through the central Northern Calcareous Alps to understand the implications of the contrasting paleogeographic models. We present (a) an interpretation based on a highly allochthonous origin of the Triassic deep-water units and (b) an interpretation based on their relative autochthony in which we incorporate the potential influence of salt tectonics in the central NCA. The restored cross-sections provide a framework within which the alternative scenarios and their paleogeographic implications can be better understood. Through this analysis we propose that salt tectonics in the central NCA can provide a valid explanation for apparent inconsistencies in the relative autochthony scenario and thus constitutes a reasonable alternative to the currently accepted allochthony scenario.

摘要

北钙质阿尔卑斯山中部(奥地利东部阿尔卑斯山)最显著的特征之一,是上三叠统深水碳酸盐岩(哈尔施塔特相)和二叠纪 - 三叠纪蒸发岩广泛分布于深水侏罗纪中层地层之上,以及其下伏的上三叠统浅水碳酸盐岩台地序列之上。传统上,哈尔施塔特相及伴生的蒸发岩被解释为要么源自与同期碳酸盐台地以南的某个位置,要么是在广阔台地范围内较深的海域中沉积形成。迄今为止,这场争论主要是通过对三叠纪和侏罗纪相在地图视图中的分布分析来解决的,然而,这种分析在一定程度上存在模糊性和主观性。在本论文中,我们首次展示了通过北钙质阿尔卑斯山中部的区域横截面的顺序恢复,以了解对比鲜明的古地理模型的含义。我们展示了(a)基于三叠纪深水单元高度异地成因的解释,以及(b)基于其相对原地成因的解释,其中我们纳入了盐构造在北钙质阿尔卑斯山中部的潜在影响。恢复后的横截面提供了一个框架,在这个框架内可以更好地理解不同的情景及其古地理意义。通过这种分析,我们提出北钙质阿尔卑斯山中部的盐构造可以为相对原地成因情景中明显的不一致提供合理的解释,因此构成了当前被接受的异地成因情景的合理替代方案。

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Emplacement and associated sedimentary record of the Jurassic submarine salt allochthon of the Wurzeralm (Eastern Alps, Austria).武泽阿尔姆(奥地利东阿尔卑斯山)侏罗纪海底盐异地岩体的位置及相关沉积记录。
Terra Nova. 2023 Dec;35(6):524-532. doi: 10.1111/ter.12675. Epub 2023 Aug 7.

本文引用的文献

1
Emplacement and associated sedimentary record of the Jurassic submarine salt allochthon of the Wurzeralm (Eastern Alps, Austria).武泽阿尔姆(奥地利东阿尔卑斯山)侏罗纪海底盐异地岩体的位置及相关沉积记录。
Terra Nova. 2023 Dec;35(6):524-532. doi: 10.1111/ter.12675. Epub 2023 Aug 7.
2
The structure of the Hallstatt evaporite body (Northern Calcareous Alps, Austria): A compressive diapir superposed by strike-slip shear?哈尔施塔特蒸发岩体的结构(奥地利北钙质阿尔卑斯山):叠加了走滑剪切作用的挤压底辟构造?
J Struct Geol. 2014 Mar;60:70-84. doi: 10.1016/j.jsg.2013.12.008.