岩体蠕变变形斜坡中长期准备因素的作用:扎格罗斯山脉带(伊朗)的启示

IF 5.8 2区 工程技术 Q1 ENGINEERING, GEOLOGICAL
Michele Delchiaro, Marta Della Seta, Salvatore Martino, Mohammad Moumeni, Reza Nozaem, Gian Marco Marmoni, Carlo Esposito
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引用次数: 0

摘要

受块状岩石蠕变变形影响的斜坡的长期演变既受时间不变的诱发因素(如地质结构继承)控制,也受时间相关的准备条件(包括区域隆起和地貌演变速度)控制。然而,深层重力斜坡变形、排水管网演化和构造之间的关系仍未明确。在此,我们重点研究了洛雷斯坦弧(伊朗扎格罗斯山脉)Siah Kuh 反斜纹东南端末端、山前断层上游约 8 平方公里区域内的一次未记录深层重力斜坡变形。为了评估该斜坡迄今为止的演变过程,我们综合运用了定量地貌分析、地貌标记的光激发发光测年和合成孔径雷达干涉测量技术。具体而言,我们半自动地提取了河流阶地,并根据相对高程模型将其与高出河谷的海拔高度联系起来,从而定义了阶地。踏面的平面高度分布与实地取样的两层地层阶地的 OSL 年龄沿河流纵剖面相互关联,从而估算出山前断层上游和下游的隆起率分别为 2.8 ± 0.2 毫米/年和 0.42 ± 0.03 毫米/年。通过处理 2014 年 10 月 6 日至 2019 年 3 月 31 日期间 279 颗卫星 Sentinel-1(A 和 B)上升和下降轨道的雷达图像,利用合成孔径雷达干涉测量法发现了与正在发生的斜坡变形相关的现今浅层地面位移。在整个褶皱轴上区分了不同的滑坡机制,旋转滑动和横向扩张被解释为同一过程的两个不同演变阶段,并通过褶皱轴在空间上进行了转换。事实上,旋转滑移机制代表了应变演化的高级阶段,而横向扩展则是较早的阶段。最后,我们推断洛雷斯坦弧斜坡变形方式和模式空间分布的变化与排水系统和构造的耦合演化密切相关。所涉及的体积(从 0.6 到 44 立方公里)、局部地形(从 400 到 2000 米)、切入速率(从 0.8 到 2.8 ± 0.2 毫米/年-1)和持续时间(从 104 到 105 年)代表了最重要的准备条件,并以具有明显不同流变行为的单元为特征的中等倾角下斜(从 8 到 25°)沉积序列为先决条件。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

The role of long-term preparatory factors in mass rock creep deforming slopes: insights from the Zagros Mts. belt (Iran)

The role of long-term preparatory factors in mass rock creep deforming slopes: insights from the Zagros Mts. belt (Iran)

The long-term evolution of slopes affected by Mass Rock Creep deformations is controlled by both time-invariant predisposing factors, such as the geo-structural inheritance, and time-dependent preparatory conditions, including regional uplift and landscape evolution rates. However, the relationship among Deep-seated Gravitational Slope Deformations, drainage network evolution, and tectonics remains poorly defined. Here, we focused on an undocumented Deep-seated Gravitational Slope Deformation affecting an area of about 8 km2 in the SE tip termination of the Siah Kuh anticline in the Lorestan arc (Zagros Mts., Iran), upstream to the Mountain Front Fault. To assess the evolution processes which involved the slope up to the present, we integrated quantitative geomorphic analysis, optically stimulated luminescence dating of geomorphic markers, and SAR interferometry techniques. In detail, we semi-automatically extracted the river terrace treads to which we associated an elevation above the thalweg based on the Relative Elevation Model allowing the order definition. The plano-altimetric distribution of the treads and the OSL ages of two levels of strath terraces sampled in the field have been correlated along the river longitudinal profile, allowing the estimation of an uplift rate of 2.8 ± 0.2 mm year−1 and 0.42 ± 0.03 mm year−1, respectively upstream and downstream of the Mountain Front Fault. SAR interferometry was used to spot present-day shallow ground displacements associated with the ongoing slope deformation, by processing 279 satellite Sentinel-1 (A and B) radar images of the ascending and descending orbit spanning from 06 October 2014 to 31 March 2019. Different landslide mechanisms were distinguished across the fold axis, rototranslative to lateral spreading interpreted as two different evolutionary stages of the same process transposed spatially through the fold axis. Indeed, the rototranslative mechanism represents an advanced stage of the strain evolution while the lateral spreading is an earlier one. Finally, we infer that the variability in the spatial distribution of the slope deformation styles and patterns in the Lorestan arc is strictly related to the coupled evolution of the drainage system and tectonics. Involved volumes (from 0.6 up to 44 km3), local relief (from 400 up to 2000 m), incision rates (from 0.8 to 2.8 ± 0.2 mm year−1), and persistence time (from 104 to 105 years) represent the most important preparatory conditions and are predisposed by a moderately dipping downslope (from 8 to 25°) sedimentary sequence characterised by units with significantly different rheological behaviour.

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来源期刊
Landslides
Landslides 地学-地球科学综合
CiteScore
13.60
自引率
14.90%
发文量
191
审稿时长
>12 weeks
期刊介绍: Landslides are gravitational mass movements of rock, debris or earth. They may occur in conjunction with other major natural disasters such as floods, earthquakes and volcanic eruptions. Expanding urbanization and changing land-use practices have increased the incidence of landslide disasters. Landslides as catastrophic events include human injury, loss of life and economic devastation and are studied as part of the fields of earth, water and engineering sciences. The aim of the journal Landslides is to be the common platform for the publication of integrated research on landslide processes, hazards, risk analysis, mitigation, and the protection of our cultural heritage and the environment. The journal publishes research papers, news of recent landslide events and information on the activities of the International Consortium on Landslides. - Landslide dynamics, mechanisms and processes - Landslide risk evaluation: hazard assessment, hazard mapping, and vulnerability assessment - Geological, Geotechnical, Hydrological and Geophysical modeling - Effects of meteorological, hydrological and global climatic change factors - Monitoring including remote sensing and other non-invasive systems - New technology, expert and intelligent systems - Application of GIS techniques - Rock slides, rock falls, debris flows, earth flows, and lateral spreads - Large-scale landslides, lahars and pyroclastic flows in volcanic zones - Marine and reservoir related landslides - Landslide related tsunamis and seiches - Landslide disasters in urban areas and along critical infrastructure - Landslides and natural resources - Land development and land-use practices - Landslide remedial measures / prevention works - Temporal and spatial prediction of landslides - Early warning and evacuation - Global landslide database
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