利用微震颤基本共振绘制基岩地形图和探测盲断层:韩国东南部浦项盆地的案例研究

Su Young Kang
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摘要

在 2017 年 5.5 级地震中,浦项盆地遭受了韩国仪器记录史上最严重的地震破坏。震害模式与径向分布存在明显差异,表明局部场地效应的重要作用。我们对这些场地效应及其在研究区域内产生地震破坏的作用的了解仍不全面,这表明有必要对浦项盆地的地下信息(包括从土壤到基岩的厚度和盆地几何形状)进行深入探讨。我们利用在 698 个地点进行的密集环境噪声测量,测量了浦项盆地的基岩深度。我们根据 698 个站点的微震水平垂直谱比(HVSR)得出的深度和主频,提出了一个盆地几何模型。大多数微地震测量结果显示出一个或多个明显的水平垂直谱峰,这意味着一个或多个强阻抗对比,推测这些峰代表每个测量点的基底和上覆盆地填充沉积物之间的界面。环境地震噪声会引起频率低至 0.32 赫兹的共振。共振频率与基岩深度之间的关系是利用 27 个钻孔的数据得出的,将邻近钻孔的测站测得的主要频率转换成强阻抗对比的相应深度。然后将该关系应用于主频,以估算整个研究区域的基岩深度。研究区域的共振频率和相应的基岩深度图显示,沿海地区的基岩深度最大。地图还显示,戈克岗断层以西地区的基频较低。结果表明,盆地结构比以前根据有限的直接钻孔观测和地表地质提出的建议更为复杂。横跨研究区域不同部分的地图和相关剖面图显示,在先前研究提出的推断盲断层附近,基岩深度发生了明显变化,这表明基于 HVSR 方法绘制的基岩深度图可用于推断先前未知的地貌,包括地表观测不到的隐蔽断层或盲断层。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Mapping bedrock topography and detecting blind faults using the fundamental resonance of microtremor: a case study of the Pohang Basin, southeastern Korea
The Pohang Basin sustained the most extensive seismic damage in the history of instrumental recording in Korea due to the 2017 Mw 5.5 earthquake. The pattern of damage shows marked differences from a radial distribution, suggesting important contributions by local site effects. Our understanding of these site effects and their role in generating seismic damage within the study area remains incomplete, which indicates the need for a thorough exploration of subsurface information, including the thickness of soil to bedrock and basin geometry, in the Pohang Basin. We measured the depth to bedrock in the Pohang Basin using dense ambient noise measurements conducted at 698 sites. We propose a model of basin geometry based on depths and dominant frequencies derived from the horizontal-to-vertical spectral ratio (HVSR) of microtremor at 698 sites. Most microseismic measurements exhibit one or more clear HVSR peak(s), implying one or more strong impedance contrast(s), which are presumed to represent the interface between the basement and overlying basin-fill sediments at each measurement site. The ambient seismic noise induces resonance at frequencies as low as 0.32 Hz. The relationship between resonance frequency and bedrock depth was derived using data from 27 boreholes to convert the dominant frequencies measured at stations adjacent to the boreholes into corresponding depths to the strong impedance contrast. The relationship was then applied to the dominant frequencies to estimate the depth to bedrock over the whole study area. Maps of resonance frequency and the corresponding depth to bedrock for the study area show that the greatest depths to bedrock are in the coastal area. The maps also reveal lower fundamental frequencies in the area west of the Gokgang Fault. The results indicate a more complex basin structure than previously proposed based on a limited number of direct borehole observations and surface geology. The maps and associated profiles across different parts of the study area show pronounced changes in bedrock depth near inferred blind faults proposed in previous studies, suggesting that maps of bedrock depth based on the HVSR method can be used to infer previously unknown features, including concealed or blind faults that are not observed at the surface.
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