Internal co-seismic deformation and curvature effect based on an analytical approach

Internal co-seismic deformation and curvature effect based on an analytical approach

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摘要 In this study, we present a new method to compute internal co-seismic deformations of a homoge- neous sphere, based on our previous approach （Dong et al. 2016）. In practical numerical computations, we consider a strike-slip point source as an example, and compute the vertical co-seismic displacement on different internal spherical surfaces （including the Earth surface）. Numerical results show that the internal co-seismic deformations are generally larger than that on the Earth surface; especially, the maximum co-seismic displacement appears around the seismic source. The co-seismic displacements are opposite in sign for the areas over and beneath the position of the seismic source. The results also indicate that the curvature effect of the internal deformation is pretty large, and larger than that on the Earth surface. The results indicate that the dislocation theory for a sphere is necessary in computing internal co-seismic deformations. In this study, we present a new method to compute internal co-seismic deformations of a homoge- neous sphere, based on our previous approach （Dong et al. 2016）. In practical numerical computations, we consider a strike-slip point source as an example, and compute the vertical co-seismic displacement on different internal spherical surfaces （including the Earth surface）. Numerical results show that the internal co-seismic deformations are generally larger than that on the Earth surface; especially, the maximum co-seismic displacement appears around the seismic source. The co-seismic displacements are opposite in sign for the areas over and beneath the position of the seismic source. The results also indicate that the curvature effect of the internal deformation is pretty large, and larger than that on the Earth surface. The results indicate that the dislocation theory for a sphere is necessary in computing internal co-seismic deformations.

作者 Jie Dong Wenke Sun

机构地区 Key Laboratory of Computational Geodynamics

出处《Earthquake Science》 CSCD 2017年第1期47-56,共10页 地震学报（英文版）

基金 supported financially by the National Natural Science Foundation of China (Nos.41331066,41604067 and 41474059) China Postdoctoral Science Foundation Funded Project (No.119103S268) CAS Key Study Program QYZDY-SSW-SYS003 the CAS/CAFEA International Partnership Program for Creative Research Teams (No.KZZD-EW-TZ-19)

关键词 Internal displacement. Curvature effect. Spherical model Internal displacement. Curvature effect. Spherical model

分类号 P315 [天文地球—地震学]

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Internal co-seismic deformation and curvature effect based on an analytical approach

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