%0 Journal Article %1 Yin2016 %A Yin, Zhi %A Xu, Caijun %A Wen, Yangmao %A Jiang, Guoyan %A Fan, Qingbiao %A Liu, Yang %D 2016 %J Geophysical Journal International %K imported nongeoinst %N 2 %P 954--970 %R 10.1093/gji/ggw060 %T A new hybrid inversion method for parametric curved faults and its application to the 2008 Wenchuan (China) earthquake %U http://dx.doi.org/10.1093/gji/ggw060 %V 205 %X Planar faults are widely adopted during inversions to determine slip distributions and fault geometries using geodetic observations; however, little research has been conducted with respect to curved faults. We attribute this to the lack of an appropriate parameterized modelling method. In this paper, we present a curved-fault modelling method (CFMM) that describes a curved fault according to specific parameters, and we also develop a corresponding hybrid iterative inversion algorithm (HIIA) to perform inversions for parametric curved-fault geometries and slips. The results of the strike-component and dip-component synthetic tests show that a complex S-shaped fault surface and a circular slip distribution are successfully recovered, indicating the strong performance of the CFMM and HIIA methods. In addition, we describe and verify a scenario for determining the number of necessary geometrical parameters for the HIIA and examine the case study of the Wenchuan earthquake, which occurred on a complex listric fault surface. During the iteration process of the HIIA, both the fault geometry and slip distribution of the Beichuan and Pengguan faults converge to optimal values, indicating a Beichuan fault (BCF) model with a continuous listric shape and gradual steepening from the southwest to the northeast, which is highly consistent with geological survey results. Both the synthetic and real-world case studies show that the HIIA and the CMFF are superior to the conventional fault modelling method based on rectangular planes and that these models have the potential for use in more integrated research involving inversion studies, such as joint slip/curved-fault-geometry inversions that take into account data resolving power.

@article{Yin2016, __markedentry = {[zach:]}, abstract = {Planar faults are widely adopted during inversions to determine slip distributions and fault geometries using geodetic observations; however, little research has been conducted with respect to curved faults. We attribute this to the lack of an appropriate parameterized modelling method. In this paper, we present a curved-fault modelling method (CFMM) that describes a curved fault according to specific parameters, and we also develop a corresponding hybrid iterative inversion algorithm (HIIA) to perform inversions for parametric curved-fault geometries and slips. The results of the strike-component and dip-component synthetic tests show that a complex S-shaped fault surface and a circular slip distribution are successfully recovered, indicating the strong performance of the CFMM and HIIA methods. In addition, we describe and verify a scenario for determining the number of necessary geometrical parameters for the HIIA and examine the case study of the Wenchuan earthquake, which occurred on a complex listric fault surface. During the iteration process of the HIIA, both the fault geometry and slip distribution of the Beichuan and Pengguan faults converge to optimal values, indicating a Beichuan fault (BCF) model with a continuous listric shape and gradual steepening from the southwest to the northeast, which is highly consistent with geological survey results. Both the synthetic and real-world case studies show that the HIIA and the CMFF are superior to the conventional fault modelling method based on rectangular planes and that these models have the potential for use in more integrated research involving inversion studies, such as joint slip/curved-fault-geometry inversions that take into account data resolving power.}, added-at = {2018-10-05T10:47:49.000+0200}, author = {Yin, Zhi and Xu, Caijun and Wen, Yangmao and Jiang, Guoyan and Fan, Qingbiao and Liu, Yang}, biburl = {https://puma.ub.uni-stuttgart.de/bibtex/27c4565d239a50a5884734f0541557419/gisitpuma}, comment = {10.1093/gji/ggw060}, doi = {10.1093/gji/ggw060}, interhash = {3dda47d1594d0025922169cdee575a25}, intrahash = {7c4565d239a50a5884734f0541557419}, issn = {0956-540X}, journal = {Geophysical Journal International}, keywords = {imported nongeoinst}, month = may, number = 2, pages = {954--970}, timestamp = {2018-12-06T09:08:50.000+0100}, title = {A new hybrid inversion method for parametric curved faults and its application to the 2008 Wenchuan (China) earthquake}, url = {http://dx.doi.org/10.1093/gji/ggw060}, volume = 205, year = 2016 }