水文驱动地壳变形并调节马特塞山丘(意大利)的地震活动

IF 2.6 3区 地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS
Francesco Pintori, Federica Sparacino, Federica Riguzzi
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引用次数: 0

摘要

我们分析了位于意大利南亚平宁山脉的马特塞山丘的水文、形变和地震之间的相互作用。我们发现,该地区的特点是两个水文驱动过程同时作用:第一个过程是全球导航卫星系统(GNSS)数据在地壳最浅部分(主要泉水海拔以上)探测到的形变,与水文作用力相一致;第二个过程是地震在深部触发,但有延迟,表明是一个向下扩散的过程。我们通过对全球导航卫星系统位移时间序列进行主成分分析来研究第一个过程,目的是找出描述最大数据方差的共同信号。我们发现,在两个全球导航卫星系统站点,与第一个主成分(PC1)相关的最大水平位移大于 1 厘米,而且 PC1 的时间演变与该地区最大泉水的流量密切相关,并处于同一相位,我们将其视为地块含水量的代表。这表明,水平变形的主要来源是马特塞含水层浅层的含水量波动,特别是位于与主要测绘断层相对应的断裂内的含水量波动。这一过程引起的变形率比构造变形率大一个数量级。最后,我们通过观察背景地震与泉水排泄量之间 121 天的相关性,推断出第二个过程。根据我们的解释,由含水层含水量变化驱动的向下扩散过程传播的孔隙压力波影响了断层的强度,有利于微地震的发生。水力扩散率(1.5 m2/s)和岩石渗透率(3.2-3.8×10-13 m2)的数值也证明了这一点,这些数值与岩溶灰岩中观察到的数值相符。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Hydrology Drives Crustal Deformation and Modulates Seismicity in the Matese Massif (Italy)
We analyze the interplay between hydrology, deformation, and seismicity in the Matese massif, located in the Italian Southern Apennines. We find that this area is characterized by the concurrent action of two hydrologically driven processes: the first is the deformation detected by the Global Navigation Satellite Systems (GNSS) data in the shallowest part (above the elevation of the major springs) of the Earth crust, in phase with the hydrological forcing; the second is the triggering of seismicity at depth with a delay suggesting a downward diffusive process. We study the first process by applying a principal component analysis to the GNSS displacements time series, aiming to identify a common signal describing the largest data variance. We find that the maximum horizontal displacements associated with the first principal component (PC1) are larger than 1 cm in two GNSS sites, and the PC1 temporal evolution is well correlated and in phase with the flow of the largest spring of the region, which we consider as proxy of the water content of the massif. This suggests that the main source of horizontal deformation is the water content fluctuations in the shallow portion of the Matese aquifer, in particular within fractures located in correspondence of the main mapped faults. The deformation rates caused by this process are one order of magnitude larger than the tectonic ones. Finally, we infer the second process by observing the correlation between the background seismicity and the spring discharge with a time lag of 121 days. In our interpretation, downward diffusive processes, driven by aquifer water content variations, propagate pore‐pressure waves that affect the fault’s strength favoring the occurrence of microearthquakes. This is supported by the values of hydraulic diffusivity (⁠1.5 m2/s⁠) and rock permeability (⁠3.2–3.8×10−13 m2⁠), which are compatible with what is observed in karstified limestones.
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来源期刊
Seismological Research Letters
Seismological Research Letters 地学-地球化学与地球物理
CiteScore
6.60
自引率
12.10%
发文量
239
审稿时长
3 months
期刊介绍: Information not localized
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