1906年维也纳盆地转移断层dobr Voda地震(M=5.7): ESI2007震级评价及余震序列分析

IF 1.7 4区地球科学 Q2 Earth and Planetary Sciences

Austrian Journal of Earth Sciences Pub Date : 2020-01-01 DOI:10.17738/ajes.2020.0003

Asma Nasir, E. Hintersberger, K. Decker

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引用次数: 2

摘要

摘要余震识别在大地震的评估和表征中起着重要作用。特别是余震序列的长度是划分地震目录的一个重要方面，因此会影响某个地区的地震频率，这对未来的地震危险性评估很重要。然而，在变形率低、地震活动性低至中等的板内地区，重大事件后的余震是否会持续更长的时间仍然值得怀疑。在这项研究中，我们使用了最早的仪器记录地震之一，1906年多布拉沃达地震（Ms/Imax=5.7/VIII-IX），来比较不同的余震确定方法及其对理解记录地震序列的适用性。维也纳盆地转移断层系统的DobráVoda段是斯洛伐克地震最活跃的地区之一，1906年的地震是有记录以来最强的地震。我们首先根据环境强度等级（ESI2007），使用地震影响的当代描述来评估地震的震中强度。该附加信息导致将最大强度约束为IESI2007＝IX。这一结果与1907年首次对Imax的评估非常一致，并表明了该强度数据的可靠性。在第二步中，绘制了距离主震震中分别13公里和26公里的两个空间窗口的地震数据。尽管由于战争时期和附近地震站的缺乏，数据的完整性存在不确定性，但地震活动的总体时间演变显然不能被描述为1906年事件后的大森型余震序列。相反，主震13公里范围内发生的地震显示，1906年事件发生后，地震活动加剧，而主震发生后几十年内，地震活动才减弱到较低水平。因此，地震活动性的下降发生在比大森关系预测的时间长得多的时间尺度上。我们得出的结论是，今天的地震活动可能仍然受到1906年地震的影响。

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The 1906 Dobrá Voda Earthquake (M=5.7) at the Vienna Basin Transfer Fault: evaluation of the ESI2007 intensity and analysis of the aftershock sequence

Abstract Aftershock identification plays an important role in the assessment and characterization of large earthquakes. Especially, the length of the aftershock sequence is an important aspect of declustering earthquake catalogues and therefore impacts the frequency of earthquakes in a certain region, which is important for future seismic hazard assessment. However, in intraplate regions with low deformation rates and low to moderate seismicity, it is still questionable if aftershocks after a major event may continue for much longer time. In this study, we use one of the earliest instrumentally recorded earthquakes, the 1906 Dobrá Voda earthquake (Ms/Imax=5.7/VIII-IX), to compare different approaches of aftershock determination and their suitability for understanding the recorded earthquake sequence. The Dobrá Voda segment of the Vienna Basin Transfer Fault System is one of the seismically most active zones in Slovakia with the 1906 earthquake as the strongest recorded earthquake. We first assess the epicentral intensity of the earthquake according to the Environmental Intensity Scale (ESI2007) using contemporary descriptions of earthquake effects. This additional information leads to constrain the maximal intensity to IESI2007=IX. This result agrees well with first the assessment of Imax in 1907 and indicates the reliability of this intensity data. In the second step, earthquake data are plotted for two spatial windows extending 13 km and 26 km from the epicenter of the mainshock, respectively. Despite uncertainties regarding the completeness of data due to war times and lack of nearby seismic stations, the overall temporal evolution of seismicity can apparently not be described as an Omori-type aftershock sequence following the event in 1906. Instead, earthquake occurrence within 13 km of the mainshock shows elevated earthquake activity right after the 1906 event that only decays to a lower level of activity within decades after the mainshock. The decline of seismicity therefore occurs over time scales which are much longer than those predicted by the Omori relation. We conclude that today’s seismic activity may still be affected by the 1906 earthquake.

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来源期刊

Austrian Journal of Earth Sciences Earth and Planetary Sciences-Paleontology

CiteScore

3.10

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： AUSTRIAN JOURNAL OF EARTH SCIENCES is the official journal of the Austrian Geological, Mineralogical and Palaeontological Societies, hosted by a country that is famous for its spectacular mountains that are the birthplace for many geological and mineralogical concepts in modern Earth science. AUSTRIAN JOURNAL OF EARTH SCIENCE focuses on all aspects relevant to the geosciences of the Alps, Bohemian Massif and surrounding areas. Contributions on other regions are welcome if they embed their findings into a conceptual framework that relates the contribution to Alpine-type orogens and Alpine regions in general, and are thus relevant to an international audience. Contributions are subject to peer review and editorial control according to SCI guidelines to ensure that the required standard of scientific excellence is maintained.