A regional scale Cretaceous transform fault zone at the northern Austroalpine margin: Geology of the western Ammergau Alps, Bavaria

IF 1.7 4区地球科学 Q2 Earth and Planetary Sciences

Austrian Journal of Earth Sciences Pub Date : 2022-01-01 DOI:10.17738/ajes.2022.0006

Anna-Katharina Sieberer, Hugo Ortner

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引用次数: 1

Abstract

Abstract We reinvestigated parts of the northern Austroalpine margin and provided structural and kinematic field data in order to interpret the kinematic relationship between the Cenoman-Randschuppe (CRS) marginal slice, Falkensteinzug (FSZ), Tannheim- and Karwendel thrust sheets occurring in a narrow strip at the northern front of the northwestern Northern Calcareous Alps (NCA). As a consequence, we propose a revised model for the tectonic evolution of the northern Austroalpine margin. As thrusting propagates from SSE to NNW (Cretaceous orogeny), the Karwendel thrust sheet (including its frontal part, the FSZ) was emplaced onto the Tannheim thrust sheet in the Albian, deduced from (i) upper-footwall deposits, the youngest sediments below the Karwendel thrust (Tannheim- and Losenstein Fms.), and (ii) thrust-sheet-top deposits unconformably overlying the deeply eroded northern Karwendel thrust sheet (Branderfleck Fm.). The future CRS marginal slice was, at that time, part of the foreland of this Early Cretaceous Alpine orogenic wedge. Pervasive overprint by sinistral shear within the CRS marginal slice and northern Tannheim thrust sheet suggests sinistral W-E striking transform faults cutting across this foreland, decoupling CRS marginal slice and FSZ from the main body of the NCA and enabling an independent evolution of the CRS marginal slice from the Early Cretaceous onwards. Subsequent Late Cretaceous and younger shortening leads to successive incorporation of Arosa zone, Rhenodanubian Flysch (RDF) and Helvetic units into the Alpine nappe stack; the Tannheim thrust representing the basal thrust of the NCA. Growth strata within thrust-sheet-top deposits (Branderfleck-Fm.) give evidence for refolding of thrust sheet boundaries. In a typical thin-skinned fold-and-thrust belt, deformation should cease towards the thrust front, whereas within the NCA it increases. An Austroalpine thrust front controlled by E-trending transform faults could cause an increase in deformation towards the most external NCA and explain the absence of the Arosa zone between Allgäu and Vienna. Such faults would most probably also cut out Lower Austroalpine units. Therefore, RDF and CRS marginal slice are juxtaposed; the latter found in the tectonic position of the Arosa zone. The presence of transform faults underlines the strong imprint of the opening of the North Atlantic Ocean on the depositional setting and tectonic evolution of the NCA.

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奥阿尔卑斯北缘白垩纪区域尺度转换断裂带:巴伐利亚州阿默高山脉西部地质

摘要我们重新研究了奥阿尔卑斯山脉北部边缘的部分地区，并提供了构造和运动学场数据，以解释Cenoman-Randschuppe（CRS）边缘切片、Falkensteinzug（FSZ）、Tannheim和Karwendel逆冲片之间的运动学关系，这些逆冲片产于北钙阿尔卑斯山脉（NCA）西北部北部前缘的一条狭长地带。因此，我们提出了一个修正的奥高山北缘构造演化模型。随着逆冲作用从SSE向NNW（白垩纪造山运动）的传播，Karwendel逆冲片（包括其前部FSZ）被侵位在阿尔比安的Tannheim逆冲片上，这是根据（i）上下盘沉积物推断出来的，即Karwende逆冲（Tannheim-和Losenstein Fms）下方最年轻的沉积物，和（ii）逆冲片顶部矿床不整合地覆盖在深度侵蚀的北部Karwendel逆冲片（Branderfleck Fm）上。当时，未来的CRS边缘切片是早白垩世阿尔卑斯造山楔的前陆的一部分。CRS边缘切片和北部Tannheim逆冲片内的左旋剪切渗透叠加表明，左旋W-E走向的转换断层横穿该前陆，使CRS边缘切片与FSZ与NCA主体脱钩，并使CRS边缘片从早白垩世开始独立演化。随后的晚白垩世和较年轻的缩短导致Arosa带、Rhenodanubian Flysch（RDF）和Helvetic单元相继并入阿尔卑斯推覆岩堆；Tannheim推力代表NCA的基础推力。逆冲片顶部矿床（Branderfleck Fm）内的生长层为逆冲片边界的再折叠提供了证据。在典型的薄皮褶皱和推力带中，变形应朝着推力前沿停止，而在NCA中，变形会增加。由E向转换断层控制的奥高山逆冲锋可能会导致向最外部NCA的变形增加，并解释Allgäu和Vienna之间Arosa带的缺失。这样的断层很可能也会切断下奥高山单元。因此，RDF和CRS边缘切片是并置的；后者发现于阿罗萨带的构造位置。转换断层的存在突显了北大西洋的开放对NCA的沉积环境和构造演化的强烈影响。

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来源期刊

Austrian Journal of Earth Sciences Earth and Planetary Sciences-Paleontology

CiteScore

3.10

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： AUSTRIAN JOURNAL OF EARTH SCIENCES is the official journal of the Austrian Geological, Mineralogical and Palaeontological Societies, hosted by a country that is famous for its spectacular mountains that are the birthplace for many geological and mineralogical concepts in modern Earth science. AUSTRIAN JOURNAL OF EARTH SCIENCE focuses on all aspects relevant to the geosciences of the Alps, Bohemian Massif and surrounding areas. Contributions on other regions are welcome if they embed their findings into a conceptual framework that relates the contribution to Alpine-type orogens and Alpine regions in general, and are thus relevant to an international audience. Contributions are subject to peer review and editorial control according to SCI guidelines to ensure that the required standard of scientific excellence is maintained.