在荷兰格罗宁根地区地面运动模型中捕捉空间变化

IF 1.6 2区地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY

Netherlands Journal of Geosciences-Geologie En Mijnbouw Pub Date : 2022-08-17 DOI:10.1017/njg.2022.13

P. Kruiver, M. Pefkos, A. Rodriguez-Marek, X. Campman, Kira Ooms-Asshoff, M. Chmiel, A. Lavoué, P. Stafford, J. van Elk

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引用次数: 2

摘要

荷兰Groningen气田的长期勘探导致诱发地震活动。在过去的九年中，一种越来越复杂的地震动模型(GMM)被开发出来，用于评估场地反应和相关的地震危险。在其他输入参数中，GMM输出强烈依赖于横波速度(V S)。迄今为止，基于土壤剖面的V S模型数据[Kruiver等，地震工程通报，15(9):3555-3580,2017;地球科学学报，96(5):515 - 523,2017)。最近，利用环境噪声表面波层析成像技术在格罗宁根气田上方建立了新的V - S剖面。这些所谓的场V S数据，即使在空间上有限，也提供了一个独立的V S来源，以检验GMM的空间变异水平是否足够。在这里，我们比较了用模型V S和场V S计算的两个地点(Borgsweer和Loppersum)的放大因子(AF) (Chmiel等人，Geophysical Journal International, 218(3)， 1781-1795, 2019和新数据)。我们在与地震风险相关的周期内(0.01-1.0 s)的AF结果表明，模型和现场V - s剖面在地球工程中普遍接受的不确定性范围内是一致的。此外，我们将Loppersum使用V S场或V S模型模拟的频谱加速度与监测期间发生的地震记录(2018年1月8日ML 3.4 Zeerijp)进行了比较。V S场和V S模型的地表谱加速度模型与格罗宁根大多数建筑物的共振周期(T = 0.2和0.3 S)的地震数据一致。这些结果证实，GMM中目前使用的V S模型捕获了场地响应的空间变异性，并为场地响应计算提供了可靠的输入。

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Capturing spatial variability in the regional Ground Motion Model of Groningen, the Netherlands

Abstract Long-term exploration of the Groningen gas field in the Netherlands led to induced seismicity. Over the past nine years, an increasingly sophisticated Ground Motion Model (GMM) has been developed to assess the site response and the related seismic hazard. The GMM output strongly depends on the shear-wave velocity (V S ), among other input parameters. To date, V S model data from soil profiles (Kruiver et al., Bulletin of Earthquake Engineering, 15(9): 3555–3580, 2017; Netherlands Journal of Geosciences, 96(5): s215–s233, 2017) have been used in the GMM. Recently, new V S profiles above the Groningen gas field were constructed using ambient noise surface wave tomography. These so-called field V S data, even though spatially limited, provide an independent source of V S to check whether the level of spatial variability in the GMM is sufficient. Here, we compared amplification factors (AF) for two sites (Borgsweer and Loppersum) calculated with the model V S and the field V S (Chmiel et al., Geophysical Journal International, 218(3), 1781–1795, 2019 and new data). Our AF results over periods relevant for seismic risk (0.01–1.0 s) show that model and field V S profiles agree within the uncertainty range generally accepted in geo-engineering. In addition, we compared modelled spectral accelerations using either field V S or model V S in Loppersum to the recordings of an earthquake that occurred during the monitoring period (ML 3.4 Zeerijp on 8 January 2018). The modelled spectral accelerations at the surface for both field V S and model V S are coherent with the earthquake data for the resonance periods representative of most buildings in Groningen (T = 0.2 and 0.3 s). These results confirm that the currently used V S model in the GMM captures spatial variability in the site response and represents reliable input for the site response calculations.

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来源期刊

Netherlands Journal of Geosciences-Geologie En Mijnbouw 地学-地球科学综合

CiteScore

4.00

自引率

25.90%

发文量

审稿时长

>12 weeks

期刊介绍： Netherlands Journal of Geosciences - Geologie en Mijnbouw is a fully open access journal which publishes papers on all aspects of geoscience, providing they are of international interest and quality. As the official publication of the ''Netherlands Journal of Geosciences'' Foundation the journal publishes new and significant research in geosciences with a regional focus on the Netherlands, the North Sea region and relevant adjacent areas. A wide range of topics within the geosciences are covered in the journal, including "geology, physical geography, geophyics, (geo-)archeology, paleontology, hydro(geo)logy, hydrocarbon exploration, modelling and visualisation." The journal is a continuation of Geologie and Mijnbouw (published by the Royal Geological and Mining Society of the Netherlands, KNGMG) and Mededelingen Nederlands Instituut voor Toegepaste Geowetenschappen (published by TNO Geological Survey of the Netherlands). The journal is published in full colour.