Structural Evolution, Exhumation Rates, and Rheology of the European Crust During Alpine Collision: Constraints From the Rotondo Granite—Gotthard Nappe

IF 3.3 1区地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS

Tectonics Pub Date : 2024-06-21 DOI:10.1029/2023tc008219

A. Ceccato, W. M. Behr, A. S. Zappone, L. Tavazzani, A. Giuliani

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Abstract

The rheology of crystalline units controls the large-scale deformation geometry and dynamics of collisional orogens. Defining a time-constrained rheological evolution of such units may help unravel the details of collisional dynamics. Here, we integrate field analysis, pseudosection calculations and in situ garnet U–Pb and mica Rb–Sr geochronology to define the structural and rheological evolution of the Rotondo granite (Gotthard nappe, Central Alps). We identify a sequence of four (D₁–D₄) deformation stages. Pre-collisional D₁ brittle faults developed before Alpine peak metamorphism, which occurred at 34–20 Ma (U–Pb garnet ages) at 590 ± 25°C and 0.9 ± 0.1 GPa. The reactivation of D₁ structures controlled the rheological evolution, from D₂ reverse mylonitic shearing at amphibolite facies (520 ± 40°C and 0.8 ± 0.1 GPa) at 18–20 Ma (white mica Rb–Sr ages), to strike-slip, brittle-ductile shearing at greenschist-facies D₃ (395 ± 25°C and 0.4 ± 0.1 GPa) at 14–15 Ma (white mica and biotite Rb–Sr ages), and then to D₄ strike-slip faulting at shallow conditions. Although highly misoriented for the Alpine collisional stress orientation, D₁ brittle structures controlled the localization of D₂ ductile mylonites accommodating fast (∼3 mm/yr) exhumation rates due to their weak shear strength (<10 MPa). This structural and rheological evolution is common across External Crystalline Massifs (e.g., Aar, Mont Blanc), suggesting that the European upper crust was extremely weak during Alpine collision, its strength controlled by weak ductile shear zones localized on pre-collisional deformation structures, that in turn controlled localized exhumation at the scale of the orogen.

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阿尔卑斯碰撞期间欧洲地壳的结构演变、排湿率和流变学：来自罗通多花岗岩-戈特哈德岩层的制约因素

结晶单元的流变控制着碰撞造山运动的大尺度变形几何和动力学。定义这类单元的时间约束流变演化可能有助于揭示碰撞动力学的细节。在这里，我们将现场分析、假吸积计算和原位石榴石U-Pb和云母Rb-Sr地质年代学结合起来，定义了罗通多花岗岩（中阿尔卑斯山脉，哥达基带）的结构和流变演化。我们确定了四个（D1-D4）变形阶段序列。碰撞前的 D1 脆性断层是在阿尔卑斯山变质峰值之前形成的，变质峰值发生在 34-20 Ma（U-Pb 石榴石年龄），温度为 590 ± 25°C，压力为 0.9 ± 0.1 GPa。D1 结构的重新激活控制了流变演化，从闪长岩面的 D2 反向麦哲伦剪切（520 ± 40°C 和 0.8 ± 0.1GPa），到 14-15 Ma 时绿泥石岩相 D3 的走向滑动、脆性-韧性剪切（395 ± 25°C 和 0.4 ± 0.1 GPa）（白云母和黑云母 Rb-Sr 年龄），再到浅层条件下的 D4 走向滑动断层。虽然在阿尔卑斯碰撞应力取向中，D1脆性结构的取向高度错误，但由于其剪切强度较弱（<10 MPa），控制了D2韧性麦饭石的定位，以适应快速（∼3 mm/yr）的出露速度。这种结构和流变演化在整个外结晶丘陵（如阿尔山、勃朗峰）都很常见，表明欧洲上地壳在阿尔卑斯山碰撞期间极其脆弱，其强度受控于碰撞前变形结构上局部的弱韧性剪切带，而这些剪切带反过来又控制着造山带尺度上的局部隆起。

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来源期刊

Tectonics 地学-地球化学与地球物理

CiteScore

7.70

自引率

9.50%

发文量

151

审稿时长

3 months

期刊介绍： Tectonics (TECT) presents original scientific contributions that describe and explain the evolution, structure, and deformation of Earth¹s lithosphere. Contributions are welcome from any relevant area of research, including field, laboratory, petrological, geochemical, geochronological, geophysical, remote-sensing, and modeling studies. Multidisciplinary studies are particularly encouraged. Tectonics welcomes studies across the range of geologic time.