Geomechanical models for induced seismicity in the Netherlands: inferences from simplified analytical, finite element and rupture model approaches

IF 1.6 2区地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY

Netherlands Journal of Geosciences-Geologie En Mijnbouw Pub Date : 2017-12-01 DOI:10.1017/njg.2017.38

J. van Wees, P. Fokker, K. van Thienen-Visser, B. Wassing, S. Osinga, B. Orlic, S. A. Ghouri, L. Buijze, M. Pluymaekers

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引用次数: 20

Abstract

Abstract In the Netherlands, over 190 gas fields of varying size have been exploited, and 15% of these have shown seismicity. The prime cause for seismicity due to gas depletion is stress changes caused by pressure depletion and by differential compaction. The observed onset of induced seismicity due to gas depletion in the Netherlands occurs after a considerable pressure drop in the gas fields. Geomechanical studies show that both the delay in the onset of induced seismicity and the nonlinear increase in seismic moment observed for the induced seismicity in the Groningen field can be explained by a model of pressure depletion, if the faults causing the induced seismicity are not critically stressed at the onset of depletion. Our model shows concave patterns of log moment with time for individual faults. This suggests that the growth of future seismicity could well be more limited than would be inferred from extrapolation of the observed trend between production or compaction and seismicity. The geomechanical models predict that seismic moment increase should slow down significantly immediately after a production decrease, independently of the decay rate of the compaction model. These findings are in agreement with the observed reduced seismicity rates in the central area of the Groningen field immediately after production decrease on 17 January 2014. The geomechanical model findings therefore support scope for mitigating induced seismicity by adjusting rates of production and associated pressure change. These simplified models cannot serve as comprehensive models for predicting induced seismicity in any particular field. To this end, a more detailed field-specific study, taking into account the full complexity of reservoir geometry, depletion history and mechanical properties, is required.

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荷兰诱发地震活动性的地质力学模型:来自简化分析、有限元和破裂模型方法的推论

在荷兰，已经开发了190多个不同规模的天然气田，其中15%显示出地震活动性。气衰竭引起地震活动的主要原因是压力衰竭和压实差异引起的应力变化。在荷兰，观测到的由天然气枯竭引起的诱发地震活动发生在气田相当大的压力下降之后。地质力学研究表明，如果引起诱发地震活动的断层在诱发地震活动开始时没有受到临界应力，则格罗宁根油田诱发地震活动发生的延迟和地震矩的非线性增加都可以用压力耗尽模型来解释。我们的模型显示单个故障的对数矩随时间的凹模式。这表明，未来地震活动性的增长很可能比从观测到的生产或压实与地震活动性之间的趋势推断出来的更为有限。地质力学模型预测，在产量下降后，地震矩的增加应立即显著减缓，与压实模型的衰减速率无关。这些发现与2014年1月17日产量下降后观察到的Groningen油田中部地区地震活动率下降的情况一致。因此，地质力学模型的发现支持了通过调整产量和相关压力变化来减轻诱发地震活动的范围。这些简化模型不能作为预测任何特定地区诱发地震活动性的综合模型。为此，需要进行更详细的实地研究，考虑到储层几何形状、衰竭历史和机械特性的全部复杂性。

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

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.