Large gravitational collapse structure on a rocky coast (Kvarner, NE Adriatic Sea)

IF 1.1 4区地球科学 Q3 GEOLOGY

Geologia Croatica Pub Date : 2023-10-16 DOI:10.4154/gc.2023.10

Čedomir Benac, Sanja Dugonjić Jovančević, Dražen Navratil, Andrea Tadić, Lovro Maglić

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引用次数: 0

Abstract

The studied rock collapse structure is located on the Liburnian coast (Rijeka Bay, channel zone of the NE Adriatic). The relief of the southern part of this coast, with a length of 6.5 km, is a large escarpment with very steep to vertical slopes reaching heights of 100 m above sea level, as a result of tectonic movements along the Kvarner fault zone. These events probably led to a sudden relaxation of the highly fractured rock mass. The progressive expansion occurred at locations where previously favourably oriented faults and fissures had formed a polygonal rock collapse resembling a rock-slide which is the focus of this study. Another aim of this study is to reconstruct and explain the complex morphological evolution of the studied landslide, from the pre-failure deformations, through the failure itself, to post-failure displacements, as well as possible future instabilities. Recent techniques to survey the instability, location and to analyse the evolution of the rupture surface and its dimensions were combined (Unmanned Aerial Vehicle, Side Scan Sonar and Remotely Operated Vehicles). The estimated total volume of displaced rock mass is 950,000 m3. The lower part of the instability phenomenon was submerged during the Holocene sea level rise. Since then, a large part of the displaced rock mass has been in a stable position, with sporadic rock falls. However, given unfavourable orientation and discontinuity characteristics, as well as unfavourable environmental influences, possible instabilities might also be expected in the future.

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岩石海岸上的大型引力坍缩结构(克瓦纳，东北亚得里亚海)

研究的岩石崩塌结构位于利比亚海岸(里耶卡湾，东亚得里亚海水道带)。这个海岸南部的地形，长6.5公里，是一个巨大的悬崖，非常陡峭的垂直斜坡达到海拔100米的高度，这是沿着Kvarner断裂带构造运动的结果。这些事件可能导致高度断裂的岩体突然松弛。渐进式扩张发生在先前有利的断层和裂缝形成类似岩石滑坡的多边形岩石崩塌的位置，这是本研究的重点。本研究的另一个目的是重建和解释所研究的滑坡的复杂形态演变，从破坏前的变形，通过破坏本身，到破坏后的位移，以及可能的未来不稳定。结合了最近的测量不稳定性、定位和分析破裂面及其尺寸演变的技术(无人机、侧扫声纳和远程操作车辆)。估计位移岩体的总体积为95万m3。在全新世海平面上升过程中，不稳定现象的下半部分被淹没。此后，大部分位移岩体处于稳定位置，偶有岩崩。然而，鉴于不利的方向和不连续特性，以及不利的环境影响，未来可能还会出现不稳定。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Geologia Croatica GEOSCIENCES, MULTIDISCIPLINARY-

CiteScore

2.90

自引率

23.10%

发文量

审稿时长

>12 weeks

期刊介绍： Geologia Croatica welcomes original scientific papers dealing with diverse aspects of geology and geological engineering, the history of the Earth, and the physical changes that the Earth has undergone or it is undergoing. The Journal covers a wide spectrum of geology disciplines (palaeontology, stratigraphy, mineralogy, sedimentology, petrology, geochemistry, structural geology, karstology, hydrogeology and engineering geology) including pedogenesis, petroleum geology and environmental geology. Papers especially concerning the Pannonian Basin, Dinarides, the Adriatic/Mediterranean region, as well as notes and reviews interesting to a wider audience (e.g. review papers, book reviews, and notes) are welcome.