Polyphase rock slope failure controlled by pre-existing geological structures and rock bridges

IF 3.7 2区 工程技术 Q3 ENGINEERING, ENVIRONMENTAL
Reinhard Gerstner, Christine Fey, Erik Kuschel, Gerald Valentin, Klaus Voit, Christian Zangerl
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引用次数: 1

Abstract

Even after decades of intensive research, assessing rock slope stability remains a challenge. One reason for this is the spatial variability of rock bridges (RBs) related to non-persistent, pre-existing geological structures, especially as the detection of RBs is generally limited to the post-failure period. Thus, the identification and classification of RBs and their inclusion in numerical studies are demanding, yet essential, since even small quantities of RBs can be decisive for rock slope stability. In our study, we demonstrate how brittle RB failure and pre-existing geological structures control the mechanisms of a polyphase rock slope failure. Therefore, we present a case study in the Austrian Alps, where three rock falls with a failure volume of 30,000 m3 occurred in 2019. Based on detailed process reconstructions, high-resolution terrain models, and comprehensive geological and rock mechanical investigations, we derived high-quality input for our distinct element model (DEM). By applying asymmetric Voronoi tessellation in the DEM, we modelled the coalescence of pre-existing geological structures by brittle RB failure. As a result, we identified toppling as the predominant failure mechanism at the study site. Distinctive geological structures decisively affected the failure mechanism. However, the toppling failure was only reproducible by incorporating RBs in the DEM in their pre-failure position. Finally, we found that joint persistence, and consequently the presence of potential RBs, controls which initial rock fall failure mechanism was developed. In conclusion, we state that the initial toppling failure of the Hüttschlag rock falls is controlled by non-persistent geological structures in interplay with RBs.

多相岩质边坡破坏受既有地质构造和岩桥控制
即使经过几十年的深入研究,评估岩质边坡的稳定性仍然是一个挑战。其中一个原因是,与非持续性、预先存在的地质结构有关的岩桥(RBs)的空间变异性,特别是对岩桥的检测通常仅限于破坏后阶段。因此,识别和分类RBs并将其纳入数值研究是非常必要的,因为即使少量RBs也可能对岩质边坡的稳定性起决定性作用。在我们的研究中,我们展示了脆性RB破坏和预先存在的地质结构如何控制多相岩质边坡破坏的机制。因此,我们在奥地利阿尔卑斯山进行了一个案例研究,该案例于2019年发生了三次岩石坠落,破坏量为30,000 m3。基于详细的过程重建、高分辨率地形模型以及全面的地质和岩石力学调查,我们为我们的不同元素模型(DEM)获得了高质量的输入。通过在DEM中应用不对称Voronoi镶嵌,我们通过脆性RB破坏模拟了已有地质构造的合并。因此,我们确定倾倒是研究地点的主要破坏机制。独特的地质构造对破坏机制有决定性的影响。然而,只有将DEM中的RBs纳入其失效前位置时,才可重现倾覆失效。最后,我们发现节理的持续存在,以及潜在RBs的存在,控制了最初的岩崩破坏机制的发展。综上所述,h ttschlag岩崩的初始倾倒破坏受与RBs相互作用的非持续性地质构造控制。
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来源期刊
Bulletin of Engineering Geology and the Environment
Bulletin of Engineering Geology and the Environment 工程技术-地球科学综合
CiteScore
7.10
自引率
11.90%
发文量
445
审稿时长
4.1 months
期刊介绍: Engineering geology is defined in the statutes of the IAEG as the science devoted to the investigation, study and solution of engineering and environmental problems which may arise as the result of the interaction between geology and the works or activities of man, as well as of the prediction of and development of measures for the prevention or remediation of geological hazards. Engineering geology embraces: • the applications/implications of the geomorphology, structural geology, and hydrogeological conditions of geological formations; • the characterisation of the mineralogical, physico-geomechanical, chemical and hydraulic properties of all earth materials involved in construction, resource recovery and environmental change; • the assessment of the mechanical and hydrological behaviour of soil and rock masses; • the prediction of changes to the above properties with time; • the determination of the parameters to be considered in the stability analysis of engineering works and earth masses.
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