Cascading rupture process of the 2021 Maduo, China earthquake revealed by the joint inversion of seismic and geodetic data
暂无分享,去创建一个
Wenbin Xu | Xiaofei Chen | Xiaoge Liu | A. Zheng | Xiangwei Yu | Wenbo Zhang | Jiaqi Qian
[1] Kejie Chen,et al. Overall subshear but locally supershear rupture of the 2021 Mw 7.4 Maduo earthquake from high-rate GNSS waveforms and three-dimensional InSAR deformation , 2022, Tectonophysics.
[2] Guangwei Zhang,et al. Nucleation mechanism of the 2021 Mw 7.4 Maduo earthquake, NE Tibetan Plateau: Insights from seismic tomography and numerical modeling , 2022, Tectonophysics.
[3] Yong Zhang,et al. Rupture process of the 2021 M7.4 Maduo earthquake and implication for deformation mode of the Songpan-Ganzi terrane in Tibetan Plateau , 2022, Proceedings of the National Academy of Sciences of the United States of America.
[4] S. Samsonov,et al. Supershear Rupture During the 2021 MW 7.4 Maduo, China, Earthquake , 2022, Geophysical Research Letters.
[5] W. Gong,et al. Bayesian Inference of Fault Slip and Coupling Along the Tuosuo Lake Segment of the Kunlun Fault, China , 2022, Geophysical Research Letters.
[6] Y. Wan,et al. Source Process Featuring Asymmetric Rupture Velocities of the 2021 Mw 7.4 Maduo, China, Earthquake from Teleseismic and Geodetic Data , 2022, Seismological Research Letters.
[7] Yueren Xu,et al. Fault Source Model and Stress Changes of the 2021 Mw 7.4 Maduo Earthquake, China, Constrained by InSAR and GPS Measurements , 2022, Bulletin of the Seismological Society of America.
[8] Tao Li,et al. Large Surface‐Rupture Gaps and Low Surface Fault Slip of the 2021 Mw 7.4 Maduo Earthquake Along a Low‐Activity Strike‐Slip Fault, Tibetan Plateau , 2022, Geophysical Research Letters.
[9] T. Wright,et al. Large‐Scale Interseismic Strain Mapping of the NE Tibetan Plateau From Sentinel‐1 Interferometry , 2022, Journal of Geophysical Research: Solid Earth.
[10] Xi-wei Xu,et al. Coseismic surface ruptures, slip distribution, and 3D seismogenic fault for the 2021 Mw 7.3 Maduo earthquake, central Tibetan Plateau, and its tectonic implications , 2022, Tectonophysics.
[11] X. Tong,et al. Coseismic Slip Model of the 2021 Maduo Earthquake, China from Sentinel-1 InSAR Observation , 2022, Remote. Sens..
[12] J. Avouac,et al. The 2021 Mw 7.4 Madoi Earthquake: An Archetype Bilateral Slip‐Pulse Rupture Arrested at a Splay Fault , 2022, Geophysical Research Letters.
[13] Jihong Liu,et al. Complete three-dimensional coseismic displacements due to the 2021 Maduo earthquake in Qinghai Province, China from Sentinel-1 and ALOS-2 SAR images , 2021, Science China Earth Sciences.
[14] Shuai Wang,et al. Resolving co- and early post-seismic slip variations of the 2021 MW 7.4 Maduo earthquake in east Bayan Har block with a block-wide distributed deformation mode from satellite synthetic aperture radar data , 2022, Earth and Planetary Physics.
[15] Jihong Liu,et al. Coseismic and Early Postseismic Slip Models of the 2021 Mw 7.4 Maduo Earthquake (Western China) Estimated by Space‐Based Geodetic Data , 2021, Geophysical Research Letters.
[16] Yunpeng Dong,et al. Crustal flow and fluids affected the 2021 M7.4 Maduo earthquake in Northeast Tibet , 2021, Journal of Asian Earth Sciences.
[17] Hongfeng Yang,et al. Complex Slip Distribution of the 2021 Mw 7.4 Maduo, China, Earthquake: An Event Occurring on the Slowly Slipping Fault , 2021, Seismological Research Letters.
[18] Y. Fialko,et al. Coseismic and Early Postseismic Deformation Due to the 2021 M7.4 Maduo (China) Earthquake , 2021 .
[19] Caijun Xu,et al. Fault Geometry and Slip Distribution of the 2021 Mw 7.4 Maduo, China, Earthquake Inferred from InSAR Measurements and Relocated Aftershocks , 2021, Seismological Research Letters.
[20] Xiaogang Song,et al. Tectonic and Geometric Control on Fault Kinematics of the 2021 Mw7.3 Maduo (China) Earthquake Inferred From Interseismic, Coseismic, and Postseismic InSAR Observations , 2021, Geophysical Research Letters.
[21] Chunyan Qu,et al. Rupture Kinematics and Coseismic Slip Model of the 2021 Mw 7.3 Maduo (China) Earthquake: Implications for the Seismic Hazard of the Kunlun Fault , 2021, Remote. Sens..
[22] L. Fang,et al. Aftershock sequence relocation of the 2021 MS7.4 Maduo Earthquake, Qinghai, China , 2021, Science China Earth Sciences.
[23] Yuchao Fu,et al. Slip rate of the seismogenic fault of the 2021 Maduo earthquake in western China inferred from GPS observations , 2021, Science China Earth Sciences.
[24] Qi-yuan Liu,et al. Growth of the Northeastern Tibetan Plateau Driven by Crustal Channel Flow: Evidence From High‐Resolution Ambient Noise Imaging , 2021, Geophysical Research Letters.
[25] Yan Liang,et al. Geophysical constraints on the nature of lithosphere in central and eastern Tibetan plateau , 2021 .
[26] OUP accepted manuscript , 2021, Geophysical Journal International.
[27] Y. Ben‐Zion,et al. The generation of large earthquakes , 2020, Nature Reviews Earth & Environment.
[28] Wenbin Xu,et al. Source Model of the 2014 Mw 6.9 Yutian Earthquake at the Southwestern End of the Altyn Tagh Fault in Tibet Estimated from Satellite Images , 2020 .
[29] W. Feng,et al. The 2018 MW 7.5 Papua New Guinea Earthquake: A Dissipative and Cascading Rupture Process , 2020, Geophysical Research Letters.
[30] Wenbin Xu,et al. A hybrid source mechanism of the 2017 Mw 6.5 Jiuzhaigou earthquake revealed by the joint inversion of strong-motion, teleseismic and InSAR data , 2020 .
[31] Zheng‐Kang Shen,et al. Present‐Day Crustal Deformation of Continental China Derived From GPS and Its Tectonic Implications , 2020, Journal of Geophysical Research: Solid Earth.
[32] Wei Wang,et al. Spatio-temporal foreshock evolution of the 2019 M 6.4 and M 7.1 Ridgecrest, California earthquakes , 2019, Earth and Planetary Science Letters.
[33] Daoyuan Sun,et al. The 2013 and 2017 Ms 5 Seismic Swarms in Jilin, NEChina: Fluid‐Triggered Earthquakes? , 2019, Journal of Geophysical Research: Solid Earth.
[34] Eric J. Fielding,et al. Early and persistent supershear rupture of the 2018 magnitude 7.5 Palu earthquake , 2019, Nature Geoscience.
[35] Xiaoli Ding,et al. The 2017 Mw 7.3 Sarpol Zahāb Earthquake, Iran: A compact blind shallow-dipping thrust event in the mountain front fault basement , 2018, Tectonophysics.
[36] C. Ji,et al. Earthquake nucleation and fault slip complexity in the lower crust of central Alaska , 2018, Nature Geoscience.
[37] J. Gomberg. Unsettled earthquake nucleation , 2018, Nature Geoscience.
[38] W. Ellsworth,et al. Nucleation of the 1999 Izmit earthquake by a triggered cascade of foreshocks , 2018, Nature Geoscience.
[39] Yan Zhan,et al. The 2017 Jiuzhaigou Earthquake: A Complicated Event Occurred in a Young Fault System , 2018 .
[40] A. Zheng,et al. Source rupture process of the 2016 Kaikoura, New Zealand earthquake estimated from the kinematic waveform inversion of strong-motion data , 2018 .
[41] M. Ishii,et al. Back-Projection Imaging of Earthquakes , 2017 .
[42] S. Wei,et al. The effects of core-reflected waves on finite fault inversions with teleseismic body wave data , 2016 .
[43] Yosuke Aoki,et al. The 2015 Wolf volcano (Galápagos) eruption studied using Sentinel‐1 and ALOS‐2 data , 2016 .
[44] Younghee Kim,et al. A seismic reference model for the crust and uppermost mantle beneath China from surface wave dispersion , 2016 .
[45] A. Lin,et al. Coseismic Surface Ruptures Associated with the 2014 Mw 6.9 Yutian Earthquake on the Altyn Tagh Fault, Tibetan Plateau , 2016 .
[46] Lion Krischer,et al. ObsPy: a bridge for seismology into the scientific Python ecosystem , 2015 .
[47] Yehuda Bock,et al. Kinematic earthquake source inversion and tsunami runup prediction with regional geophysical data , 2015 .
[48] C. Werner,et al. Sentinel-1 support in the GAMMA Software , 2015 .
[49] Rongjiang Wang,et al. Stress evolution and seismic hazard on the Maqin-Maqu segment of East Kunlun Fault zone from co-, post- and interseismic stress changes , 2015 .
[50] J. Shaw,et al. Structural geometry of the source region for the 2013 Mw 6.6 Lushan earthquake: Implication for earthquake hazard assessment along the Longmen Shan , 2014 .
[51] Hua Liao,et al. GPS constrained coseismic source and slip distribution of the 2013 Mw6.6 Lushan, China, earthquake and its tectonic implications , 2014 .
[52] Xi-wei Xu,et al. Millennial slip rates of the Tazang fault, the eastern termination of Kunlun fault: Implications for strain partitioning in eastern Tibet , 2013 .
[53] Remko Scharroo,et al. Generic Mapping Tools: Improved Version Released , 2013 .
[54] D. Marsan,et al. The long precursory phase of most large interplate earthquakes , 2013 .
[55] P. Shearer,et al. Subevent location and rupture imaging using iterative backprojection for the 2011 Tohoku Mw 9.0 earthquake , 2012 .
[56] Göran Ekström,et al. The global CMT project 2004–2010: Centroid-moment tensors for 13,017 earthquakes , 2012 .
[57] Hiroo Kanamori,et al. W phase source inversion for moderate to large earthquakes (1990–2010) , 2012 .
[58] Naoshi Hirata,et al. Propagation of Slow Slip Leading Up to the 2011 Mw 9.0 Tohoku-Oki Earthquake , 2012, Science.
[59] James Jackson,et al. The 2010 MW 6.8 Yushu (Qinghai, China) earthquake: Constraints provided by InSAR and body wave seismology , 2011 .
[60] Xi-wei Xu,et al. Rupture segmentation and slip partitioning of the mid-eastern part of the Kunlun Fault, north Tibetan Plateau , 2011 .
[61] XU Caijun,et al. Rupture of deep faults in the 2008 Wenchuan earthquake and uplift of the Longmen Shan , 2011 .
[62] Zhiwei Li,et al. Crustal P-wave velocity structure of the Longmenshan region and its tectonic implications for the 2008 Wenchuan earthquake , 2011 .
[63] Jean-Paul Ampuero,et al. A window into the complexity of the dynamic rupture of the 2011 Mw 9 Tohoku‐Oki earthquake , 2011 .
[64] Jian Lin,et al. Coulomb 3.3 Graphic-rich deformation and stress-change software for earthquake, tectonic, and volcano research and teaching-user guide , 2011 .
[65] Yun‐tai Chen,et al. Source process of the 2010 Yushu, Qinghai, earthquake , 2010 .
[66] Peizhen Zhang,et al. Slip maxima at fault junctions and rupturing of barriers during the 2008 Wenchuan earthquake , 2009 .
[67] H. Kanamori,et al. Source Inversion of the W-Phase: Real-time Implementation and Extension to Low Magnitudes , 2009 .
[68] Ying Chun Li,et al. Source mechanism of strong aftershocks (Ms⩾5.6) of the 2008/05/12 Wenchuan earthquake and the implication for seismotectonics , 2009 .
[69] Zhiwei Li,et al. Improved filtering parameter determination for the goldstein radar interferogram filter , 2008 .
[70] Hiroo Kanamori,et al. Source inversion of W phase: speeding up seismic tsunami warning , 2008 .
[71] B. Burchfiel,et al. The Geological Evolution of the Tibetan Plateau , 2008, Science.
[72] D. Marsan,et al. Extending Earthquakes' Reach Through Cascading , 2008, Science.
[73] Chun-yong Wang,et al. S-wave crustal and upper mantle’s velocity structure in the eastern Tibetan Plateau — Deep environment of lower crustal flow , 2008 .
[74] Xi-wei Xu,et al. Background and precursory seismicities along and surrounding the Kunlun fault before the Ms8.1, 2001, Kokoxili earthquake, China , 2007 .
[75] A. Lin,et al. Surface Ruptures Associated with the 1937 M 7.5 Tuosuo Lake and the 1963 M 7.0 Alake Lake Earthquakes and the Paleoseismicity along the Tuosuo Lake Segment of the Kunlun Fault, Northern Tibet , 2007 .
[76] E. Kirby,et al. Slip rate gradients along the eastern Kunlun fault , 2007 .
[77] T. Brocher. Empirical relations between elastic wavespeeds and density in the Earth's crust , 2005 .
[78] J. M. Bush,et al. Dynamic topography produced by lower crustal flow against rheological strength heterogeneities bordering the Tibetan Plateau , 2005 .
[79] Peter M. Shearer,et al. Extent, duration and speed of the 2004 Sumatra–Andaman earthquake imaged by the Hi-Net array , 2005, Nature.
[80] Matthias Ohrnberger,et al. Tracking the rupture of the Mw = 9.3 Sumatra earthquake over 1,150 km at teleseismic distance , 2005, Nature.
[81] A. Freed. EARTHQUAKE TRIGGERING BY STATIC, DYNAMIC, AND POSTSEISMIC STRESS TRANSFER , 2005 .
[82] R. Stein,et al. Earthquake conversations. , 2003, Scientific American.
[83] H. Zebker,et al. Fault Slip Distribution of the 1999 Mw 7.1 Hector Mine, California, Earthquake, Estimated from Satellite Radar and GPS Measurements , 2002 .
[84] Luis Rivera,et al. A note on the dynamic and static displacements from a point source in multilayered media , 2002 .
[85] Bertrand Meyer,et al. Oblique Stepwise Rise and Growth of the Tibet Plateau , 2001, Science.
[86] C. W. Chen,et al. Two-dimensional phase unwrapping with use of statistical models for cost functions in nonlinear optimization. , 2001, Journal of the Optical Society of America. A, Optics, image science, and vision.
[87] S. Deng,et al. Klukiopsis jurassica—A new Jurassic schizaeaceous fern from China , 2000 .
[88] Leigh H. Royden,et al. Topographic ooze: Building the eastern margin of Tibet by lower crustal flow , 2000 .
[89] David A. Seal,et al. The Shuttle Radar Topography Mission , 2007 .
[90] R. Stein. The role of stress transfer in earthquake occurrence , 1999, Nature.
[91] E. Hauksson,et al. The static stress change triggering model: Constraints from two southern California aftershock sequences , 1998 .
[92] Wang,et al. Surface Deformation and Lower Crustal Flow in Eastern Tibet , 1997, Science.
[93] Gregory C. Beroza,et al. Properties of the seismic nucleation phase , 1996 .
[94] Thomas H. Heaton,et al. The slip history of the 1994 Northridge, California, earthquake determined from strong-motion, teleseismic, GPS, and leveling data , 1996, Bulletin of the Seismological Society of America.
[95] W. Ellsworth,et al. Seismic Evidence for an Earthquake Nucleation Phase , 1995, Science.
[96] G. King,et al. STATIC STRESS CHANGES AND THE TRIGGERING OF EARTHQUAKES , 1994 .
[97] P. Molnar,et al. FAULTING ASSOCIATED WITH LARGE EARTHQUAKES AND THE AVERAGE , 1984 .
[98] Thomas H. Heaton,et al. Inversion of strong ground motion and teleseismic waveform data for the fault rupture history of the 1979 Imperial Valley, California, earthquake , 1983 .
[99] P. R. Cobbold,et al. Propagating extrusion tectonics in Asia: New insights from simple experiments with plasticine , 1982 .
[100] Allen H. Olson,et al. Finite faults and inverse theory with applications to the 1979 Imperial Valley earthquake , 1982 .
[101] D. L. Anderson,et al. Preliminary reference earth model , 1981 .
[102] D. Boore,et al. Control of rupture by fault geometry during the 1966 parkfield earthquake , 1981 .
[103] Peter Molnar,et al. Active faulting and tectonics in China , 1977 .
[104] P. Molnar,et al. Cenozoic Tectonics of Asia: Effects of a Continental Collision: Features of recent continental tectonics in Asia can be interpreted as results of the India-Eurasia collision. , 1975, Science.