Mega-Folding of a Basement During Incipient Intra-Plate Continental Subduction (Alpine Central Iberia)

IF 3.3 1区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS Tectonics Pub Date : 2024-04-05 DOI:10.1029/2023tc008163
Rubén Díez Fernández, Gerardo de Vicente, Diana Moreno-Martín, Carlos Fernández, Ricardo Arenas, Francisco J. Rubio Pascual
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Abstract

Metamorphic basements are usually considered rigid and isotropic at a large scale. However, basements contain inherited weaknesses that may potentially accommodate superimposed contraction (e.g., fault reactivation), and that favor fold nucleation (e.g., penetrative foliations). If these conditions are met, what could be the factors that impede the development of basement folds or their recognition? Actual basement folding is rarely documented, especially for large dimensions. Here we provide a case example, discussed from the perspective of structural analysis of surface data and sustained by geophysical data. The basement of the Spanish-Portuguese Central System is defined by an Alpine mega-fold (Hiendelaencina Antiform) that trends parallel to this mountain range and affects the basement and its sedimentary cover, collectively. The wavelength of this fold matches or even surpasses the thickness of the crust that hosts it (36–41 km). The Moho under this mega-fold is displaced by an Alpine fault that accounts for incipient intraplate continental subduction. The topography of the mantle may reflect an up-warping compatible with the mega-fold observed on the surface. Mega-folding is observed in the hanging wall of the Berzosa Fault, which emerges as a SE-dipping, Variscan (Paleozoic), extensional fault reactivated as a basal decollement upon Alpine (Cenozoic) contraction. The mega-fold was formed after well-oriented planar anisotropies in the basement (foliation and bedding). The development of this fold was assisted by heterogeneous shearing (coeval thrusting) plus the buttressing effect of pre-existing, near-vertical, crustal-scale faults (Somolinos and Somosierra), which inhibited slip-upsection through the basal decollement (Berzosa Fault).
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板内大陆俯冲初期的基底大褶皱(伊比利亚中部高山地区)
变质基底通常被认为是刚性的,在大尺度上各向同性。然而,基底含有遗传性弱点,有可能容纳叠加收缩(如断层再活化),并有利于褶皱成核(如穿透性褶皱)。如果满足这些条件,那么阻碍基底褶皱发展或识别基底褶皱的因素可能是什么?实际的基底褶皱很少有文献记载,尤其是大尺寸的基底褶皱。在此,我们提供一个案例,从地表数据的结构分析角度进行讨论,并以地球物理数据为依据。西班牙-葡萄牙中央系统的基底由阿尔卑斯山巨型褶皱(Hiendelaencina Antiform)所界定,其走向与山脉平行,并对基底及其沉积覆盖层产生整体影响。该褶皱的波长与其所在地壳的厚度(36-41 千米)相当,甚至超过了后者。该巨型褶皱下的莫霍面被一条阿尔卑斯山断层位移,这说明板内大陆俯冲的萌芽。地幔的地形可能反映了与地表观测到的巨褶皱相一致的上翘。在贝尔佐萨断层的悬壁上观察到了巨型褶皱,该断层是一条向东南倾斜的瓦里斯山(古生代)伸展断层,在阿尔卑斯山(新生代)收缩时作为基底解理重新激活。巨型褶皱是在基底(褶皱和层理)定向良好的平面各向异性之后形成的。这一褶皱的形成得益于异质剪切作用(共生推力)以及先前存在的近垂直地壳尺度断层(索莫利诺斯断层和索莫西拉断层)的支撑作用,后者抑制了通过基底断层(贝尔佐萨断层)的上滑。
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来源期刊
Tectonics
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.
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