Jennifer L. Harding, Leiph A. Preston, Miles A. Bodmer
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Seismic velocities are imaged as deep as ∼700 m in areas and generally align with geologic and structural expectations. VP and VS are relatively reduced near mapped and inferred faults, with the most prominent lower VP and VS zone around the densest collection of faults. We image VP/VS ratios ranging from ∼1.5 to ∼2.4, the extremes of which occur at a depth of ∼100 m and are juxtaposed across a fault. One possible interpretation of the imaged seismic velocities is enhanced fault damage near the densest collection of faults with relatively higher porosity and/or crack density at ∼100 m depth, with patches of semiperched groundwater present in the sedimentary rock in higher VP/VS areas and drier rock in lower VP/VS areas. A relatively higher VP/VS area beneath the densest faults persists at depth, which suggests percolation of groundwater via the fault damage zone to the regionally connected lower carbonate aquifer. 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引用次数: 0
摘要
岩石谷断层带(RVFZ)是内华达州国家安全地点(NNSS)南部的板内走向滑动断层带,1993 年发生了一系列很浅(<3 公里)的地震。RVFZ 在 NNSS 内也可能具有重要的水文意义,有可能在区域地下水流中发挥作用,但当地缺乏水文数据。2021 年春,我们采集了 RVFZ 部分地区的主动源加速重力落差地震数据,以更好地描述浅层地下的特征。我们手动选取了 17,000 个 P 波行进时间和 14,000 多个 S 波行进时间,并在三维联合层析反演方案中对其进行了 P 波速度 (VP)、S 波速度 (VS) 和 VP/VS 比值反演。地震波速度成像区域最深处达 700 米,总体上与地质和构造预期一致。在测绘和推断的断层附近,VP 和 VS 相对减小,在最密集的断层群周围,VP 和 VS 较低的区域最为突出。我们拍摄到的 VP/VS 比率范围在 1.5 至 2.4 之间,其极端值出现在深度为 100 米的断层上。对成像地震速度的一种可能解释是,在 100 米深处孔隙度和/或裂缝密度相对较高的断层密集区附近,断层破坏加剧,在 VP/VS 较高区域的沉积岩中存在成片的半陡峭地下水,而在 VP/VS 较低区域的岩石则较为干燥。在密度最大的断层下方,VP/VS 相对较高的区域在深度上持续存在,这表明地下水通过断层破坏带渗入到区域相连的下碳酸盐岩含水层。地下水的存在和流动可能在 1993 年地震余震中发挥了作用。
Hydrologic Impacts of a Strike‐Slip Fault Zone: Insights from Joint 3D Body‐Wave Tomography of Rock Valley
The Rock Valley fault zone (RVFZ), an intraplate strike‐slip fault zone in the southern Nevada National Security Site (NNSS), hosted a series of very shallow (<3 km) earthquakes in 1993. The RVFZ may also have hydrological significance within the NNSS, potentially playing a role in regional groundwater flow, but there is a lack of local hydrological data. In the Spring of 2021, we collected active‐source accelerated weight drop seismic data over part of the RVFZ to better characterize the shallow subsurface. We manually picked ∼17,000 P‐wave travel times and over 14,000 S‐wave travel times, which were inverted for P‐wave velocity (VP), S‐wave velocity (VS), and VP/VS ratio in a 3D joint tomographic inversion scheme. Seismic velocities are imaged as deep as ∼700 m in areas and generally align with geologic and structural expectations. VP and VS are relatively reduced near mapped and inferred faults, with the most prominent lower VP and VS zone around the densest collection of faults. We image VP/VS ratios ranging from ∼1.5 to ∼2.4, the extremes of which occur at a depth of ∼100 m and are juxtaposed across a fault. One possible interpretation of the imaged seismic velocities is enhanced fault damage near the densest collection of faults with relatively higher porosity and/or crack density at ∼100 m depth, with patches of semiperched groundwater present in the sedimentary rock in higher VP/VS areas and drier rock in lower VP/VS areas. A relatively higher VP/VS area beneath the densest faults persists at depth, which suggests percolation of groundwater via the fault damage zone to the regionally connected lower carbonate aquifer. Potentially, the presence and movement of groundwater may have played a role in the 1993 earthquake aftershocks.
期刊介绍:
The Bulletin of the Seismological Society of America, commonly referred to as BSSA, (ISSN 0037-1106) is the premier journal of advanced research in earthquake seismology and related disciplines. It first appeared in 1911 and became a bimonthly in 1963. Each issue is composed of scientific papers on the various aspects of seismology, including investigation of specific earthquakes, theoretical and observational studies of seismic waves, inverse methods for determining the structure of the Earth or the dynamics of the earthquake source, seismometry, earthquake hazard and risk estimation, seismotectonics, and earthquake engineering. Special issues focus on important earthquakes or rapidly changing topics in seismology. BSSA is published by the Seismological Society of America.