Cassie Gann-Phillips, Ashly Cabas, Chunyang Ji, Chris Cramer, James Kaklamanos, Oliver Boyd
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A reference rock V<jats:sub>S</jats:sub> of 3000 m/s has been assumed at the bottom of the sedimentary columns, which corresponds to the base of Cretaceous and Mesozoic sediments underlying the Atlantic CP and the Gulf CP, respectively. Measured V<jats:sub>S</jats:sub> profiles located throughout the CPs are sorted into five geologic groups of varying age, and median V<jats:sub>S</jats:sub> profiles are developed for each group by combining measured V<jats:sub>S</jats:sub> values within layer thicknesses defined by an assumed layering ratio. Statistical analyses are also conducted to test the appropriateness of the selected groups. A power law model with geology-informed coefficients is used to extend the median velocity models beyond the depths where measured data were available. The median V<jats:sub>S</jats:sub> profiles provide reasonable agreement with other generic models applicable for the region, but they also incorporate new information that enables more advanced characterizations of site response at regional scales and their effective incorporation into seismic hazard models and building codes. 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引用次数: 0
摘要
大西洋和海湾沿海平原(CPs)的特点是低速沉积物和沉积岩广泛堆积,覆盖在高速基岩之上。地质和沉积厚度在很大程度上影响着地震波的传播,但目前的区域地动放大和地震灾害模型对这些场地条件的描述十分有限。在本研究中,通过整合剪切波速度(VS)测量、地表地质以及最近为 CPs 开发的沉积厚度模型,为 CPs 建立了一个新的区域地震速度模型。假定沉积柱底部的参考岩石 VS 为 3000 米/秒,这分别相当于大西洋断裂带和海湾断裂带下白垩纪和中生代沉积物的底部。位于整个大陆坡的测量到的 VS 剖面被分为五个不同年龄的地质组,每组的 VS 剖面中值是通过合并按假定分层率确定的层厚内的测量 VS 值而得出的。此外,还进行了统计分析,以检验所选组别的适当性。使用带有地质信息系数的幂律模型,将中值速度模型扩展到可获得测量数据的深度之外。中值 VS 剖面与适用于该地区的其他通用模型具有合理的一致性,但它们也包含了新的信息,能够更先进地描述区域范围内的场地响应特征,并有效地将其纳入地震灾害模型和建筑规范中。建议的中值速度剖面可根据地表地质单元的空间分布分配到基于网格的 CPs 模型中。
Regional seismic velocity model for the U.S. Atlantic and Gulf Coastal Plains based on measured shear wave velocity, sediment thickness, and surface geology
The Atlantic and Gulf Coastal Plains (CPs) are characterized by widespread accumulations of low-velocity sediments and sedimentary rock that overlay high-velocity bedrock. Geology and sediment thickness greatly influence seismic wave propagation, but current regional ground motion amplification and seismic hazard models include limited characterization of these site conditions. In this study, a new regional seismic velocity model for the CPs is created by integrating shear wave velocity (VS) measurements, surface geology, and a sediment thickness model recently developed for the CPs. A reference rock VS of 3000 m/s has been assumed at the bottom of the sedimentary columns, which corresponds to the base of Cretaceous and Mesozoic sediments underlying the Atlantic CP and the Gulf CP, respectively. Measured VS profiles located throughout the CPs are sorted into five geologic groups of varying age, and median VS profiles are developed for each group by combining measured VS values within layer thicknesses defined by an assumed layering ratio. Statistical analyses are also conducted to test the appropriateness of the selected groups. A power law model with geology-informed coefficients is used to extend the median velocity models beyond the depths where measured data were available. The median VS profiles provide reasonable agreement with other generic models applicable for the region, but they also incorporate new information that enables more advanced characterizations of site response at regional scales and their effective incorporation into seismic hazard models and building codes. The proposed median velocity profiles can be assigned within a grid-based model of the CPs according to the spatial distribution of geologic units at the surface.
期刊介绍:
Earthquake Spectra, the professional peer-reviewed journal of the Earthquake Engineering Research Institute (EERI), serves as the publication of record for the development of earthquake engineering practice, earthquake codes and regulations, earthquake public policy, and earthquake investigation reports. The journal is published quarterly in both printed and online editions in February, May, August, and November, with additional special edition issues.
EERI established Earthquake Spectra with the purpose of improving the practice of earthquake hazards mitigation, preparedness, and recovery — serving the informational needs of the diverse professionals engaged in earthquake risk reduction: civil, geotechnical, mechanical, and structural engineers; geologists, seismologists, and other earth scientists; architects and city planners; public officials; social scientists; and researchers.