M. Pischiutta, Lawrence M. Baker, Jon B. Fletcher, Francesco Salvini, A. Rovelli, Y. Ben‐Zion
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Aside from the well-known effect of fault-trapped waves in the low-velocity zone with polarization azimuths parallel to the fault strike, the effect of stiffness anisotropy was recently recognized with polarization azimuths at high-angle to the fault strike and orthogonal to the locally predominant fracture field in the fault damage zone. To clarify further such features, we investigate directional amplification effects across the San Jacinto fault zone in Southern California using seismic data recorded by permanent seismic stations and dense across-fault arrays. We observe three main polarization trends. The first trend parallel to the fault strike is ascribed to fault-trapped waves along the low-velocity zone, in agreement with several studies in the last decade in the same region. The second and third trends are orthogonal to the orientation of R and T Riedel planes, respectively. They are related to the stiffness anisotropy in densely fractured rocks in the damage zone, which are more compliant orthogonal to their fractures. At some locations the two effects are superimposed, occurring in different and distinct frequency ranges. Directional amplification at rock sites can be important for expected ground motion and seismic hazard. However, in seismic engineering the current prescriptions of seismic codes do not account for amplification effects at rock sites at frequencies of engineering interest.","PeriodicalId":502458,"journal":{"name":"Geophysical Journal International","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2024-06-11","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Directional amplification across the San Jacinto fault zone, CA\",\"authors\":\"M. Pischiutta, Lawrence M. Baker, Jon B. Fletcher, Francesco Salvini, A. Rovelli, Y. 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引用次数: 0
摘要
地表地面运动的振幅、频率和极化会受到当地地质的影响。低速沉积物和填充物会放大某些频率范围内的地表运动,而断层带中的低速也会产生明显的小波。在本文中,我们提供了进一步的证据,证明地表运动的极化可能会受到断层带地质结构的影响,因为断层带承受了巨大的脆性变形。除了众所周知的极化方位角与断层走向平行的低速区断层陷波效应之外,最近还发现了刚度各向异性效应,即极化方位角与断层走向呈高角度,并与断层破坏区局部主要断裂场呈正交。为了进一步阐明这些特征,我们利用永久地震台和密集的跨断层阵列记录的地震数据,研究了南加州圣哈辛托断层带的定向放大效应。我们观察到三种主要的极化趋势。第一种趋势与断层走向平行,归因于沿低速区的断层捕获波,这与过去十年在同一地区进行的几项研究结果一致。第二和第三种趋势分别与 R 和 T 里德尔平面的方向正交。它们与破坏区密集断裂岩石的刚度各向异性有关,这些岩石的顺应性更强,与断裂方向正交。在某些位置,这两种效应是叠加的,出现在不同的频率范围内。岩石部位的定向放大效应对预期地动和地震灾害非常重要。然而,在地震工程中,目前的地震规范并没有考虑到岩层在工程频率上的放大效应。
Directional amplification across the San Jacinto fault zone, CA
The amplitude, frequency and polarization of ground motion at the surface can be affected by the local geology. While low-velocity sediments and fill can amplify ground motions in certain frequency ranges, the low velocities found in fault zones can also produce prominent wavelets. In this paper we provide further evidence that polarization of ground motion can be affected by the geologic fabric in fault zones that have sustained significant brittle deformation. Aside from the well-known effect of fault-trapped waves in the low-velocity zone with polarization azimuths parallel to the fault strike, the effect of stiffness anisotropy was recently recognized with polarization azimuths at high-angle to the fault strike and orthogonal to the locally predominant fracture field in the fault damage zone. To clarify further such features, we investigate directional amplification effects across the San Jacinto fault zone in Southern California using seismic data recorded by permanent seismic stations and dense across-fault arrays. We observe three main polarization trends. The first trend parallel to the fault strike is ascribed to fault-trapped waves along the low-velocity zone, in agreement with several studies in the last decade in the same region. The second and third trends are orthogonal to the orientation of R and T Riedel planes, respectively. They are related to the stiffness anisotropy in densely fractured rocks in the damage zone, which are more compliant orthogonal to their fractures. At some locations the two effects are superimposed, occurring in different and distinct frequency ranges. Directional amplification at rock sites can be important for expected ground motion and seismic hazard. However, in seismic engineering the current prescriptions of seismic codes do not account for amplification effects at rock sites at frequencies of engineering interest.