大型金星日冕的结构分析和演变:从金星冠边缘低角度断层中获得的启示

IF 1.8 4区 物理与天体物理 Q3 ASTRONOMY & ASTROPHYSICS Planetary and Space Science Pub Date : 2024-08-20 DOI:10.1016/j.pss.2024.105955
Thomas Kenkmann, Oguzcan Karagoz, Antonia Veitengruber
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引用次数: 0

摘要

我们利用麦哲伦合成孔径雷达图像分析了不对称的阿塔申西克日冕(直径700×900千米)(以前称为拉托纳日冕)及其周围槽的地形、断裂模式和断层,并将结果与较小的卵形迪迪利亚日冕(直径400×450千米)和帕夫洛瓦日冕(直径550×650千米)进行比较,以深入了解金星日冕的形成。阿塔亨西克包含高密度的径向、斜向和同心断裂,推断后者是最年轻的断裂。同心断裂的高密度尤其出现在外侧隆起的地方,这表明在日冕形成的后期,岩石圈的这一部分发生了弹性向下弯曲。在阿塔申斯克弧形槽的陡峭内坡上,大尺度断层暴露出来,这些断层向日冕中心缓缓倾斜,并与所有断裂交叉。我们认为,这些低角度断层最初是作为推力面形成的,但后来又重新活化为低角度正断层,从而暴露出部分断层面。我们提出了一个大日冕的现象学形成模型:日冕的形成始于径向断裂,而径向断裂是由堤坝位移和热天成层地幔羽流上升导致的日冕中心热抬升引起的。隆起和侧向羽流扩张使隆起外缘变得陡峭,并导致中央火山大厦和日冕外缘发生强烈的径向断裂。这一中间阶段保留在几个演化程度较低的日冕中,如迪迪利亚日冕和帕夫洛娃日冕。断裂的海脊沿着强烈的局部推力平面向外推挤到完整的、较冷的岩石圈上。被过度推挤的较冷岩石圈向下弹性弯曲,形成弧形槽和相关的外隆起,沿其波峰线有许多同心断裂。日冕的断裂环脊由日冕周围完整和增厚的岩石圈支撑。阿塔申西克日冕目前的形态表明,由于羽流活动的减少和热浮力的降低,其中央部分随后出现了下沉。日冕内部的下沉、高耸的日冕环的重力不稳定性以及缺乏缩短,导致推力重新激活,形成低角度的正断层。根据结构数据推导出的演化序列与涉及羽流边缘弯曲岩石圈的日冕形成的地球动力学模型相一致。
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Structural analysis and evolution of large Venusian coronae: Insights from low-angle faults at coronae rims

We analyzed topography, fracture patterns, and faults of the asymmetric Atahensik Corona (700 × 900 km diameter), formerly known as Latona Corona, and their surrounding troughs using Magellan SAR imagery, and compare the results with the smaller, ovoid Didilia (400 × 450 km diameter) and Pavlova coronae (550 × 650 km diameter) to get insights on corona formation on Venus. Atahensik contains a high density of radial, oblique, and concentric fractures, the latter are inferred to be the youngest fractures. A high density of concentric fractures particularly occurs along the outer rise and indicates elastic downward bending of this part of the lithosphere in the later stage of corona formation. Along the steep inner slopes of Atahensik's arcuate troughs, large-scale faults are exposed that dip gently towards the corona center and crosscut all fractures. We propose that these low-angle faults were initially formed as thrust planes but subsequently became reactivated as low-angle normal faults, thereby exposing parts of their fault surfaces. Such faults have been identified not only along the arcuate troughs of Atahensik but also occur in Dali Chasma, northwest of Atahensik Corona.

A phenomenological formation model of large coronae is presented: corona initiation starts with radial fracturing, which is caused by the dike emplacement and thermal uplift of the corona center due to the rise of a hot asthenospheric mantle plume. Uplift and lateral plume spreading steepen the outer rim of the uplift and cause intense radial fracturing of a central volcanic edifice and the corona's outer rim. This intermediate stage is preserved in several less-evolved coronae such as Didilia and Pavlova Coronae. The fractured ridge thrusts outward onto an intact and cooler lithosphere along strongly localized thrust planes. The overthrusted, cooler lithosphere is elastically bent downward and forms arcuate troughs and associated outer rises with numerous concentric fractures along their crest line. The fractured ridge annulus of the corona is supported by the intact and thickened lithosphere surrounding the corona. The present morphology of Atahensik Corona indicates subsequent subsidence in its central part due to declining plume activity and reduced thermal buoyancy. Reactivation of the thrusts as low-angle normal faults results from the subsidence of the corona interior, a gravitational instability of the elevated corona annulus, and a lack of shortening. The evolutionary sequence derived on the basis of structural data is in agreement with geodynamic models on corona formation involving a bending lithosphere at the plume margin.

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来源期刊
Planetary and Space Science
Planetary and Space Science 地学天文-天文与天体物理
CiteScore
5.40
自引率
4.20%
发文量
126
审稿时长
15 weeks
期刊介绍: Planetary and Space Science publishes original articles as well as short communications (letters). Ground-based and space-borne instrumentation and laboratory simulation of solar system processes are included. The following fields of planetary and solar system research are covered: • Celestial mechanics, including dynamical evolution of the solar system, gravitational captures and resonances, relativistic effects, tracking and dynamics • Cosmochemistry and origin, including all aspects of the formation and initial physical and chemical evolution of the solar system • Terrestrial planets and satellites, including the physics of the interiors, geology and morphology of the surfaces, tectonics, mineralogy and dating • Outer planets and satellites, including formation and evolution, remote sensing at all wavelengths and in situ measurements • Planetary atmospheres, including formation and evolution, circulation and meteorology, boundary layers, remote sensing and laboratory simulation • Planetary magnetospheres and ionospheres, including origin of magnetic fields, magnetospheric plasma and radiation belts, and their interaction with the sun, the solar wind and satellites • Small bodies, dust and rings, including asteroids, comets and zodiacal light and their interaction with the solar radiation and the solar wind • Exobiology, including origin of life, detection of planetary ecosystems and pre-biological phenomena in the solar system and laboratory simulations • Extrasolar systems, including the detection and/or the detectability of exoplanets and planetary systems, their formation and evolution, the physical and chemical properties of the exoplanets • History of planetary and space research
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