|本期目录/Table of Contents|

[1]张晨,季灵运,朱良玉,等.基于震源应力与GPS应变分析喜马拉雅东构造结及其邻区地壳变形特征[J].地震研究,2022,45(04):526-534.[doi:10.20015/j.cnki.ISSN1000-0666.2022.0051]
 ZHANG Chen,JI Lingyun,ZHU Liangyu,et al.Analysis of the Crustal Deformation of the Eastern Himalayan Syntaxis and Its Adjacent Areas Based on the Earthquake Focal Stress and GPS Strain[J].Journal of Seismological Research,2022,45(04):526-534.[doi:10.20015/j.cnki.ISSN1000-0666.2022.0051]
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基于震源应力与GPS应变分析喜马拉雅东构造结及其邻区地壳变形特征(PDF/HTML)

《地震研究》[ISSN:1000-0666/CN:53-1062/P]

卷:
45
期数:
2022年04期
页码:
526-534
栏目:
出版日期:
2022-08-20

文章信息/Info

Title:
Analysis of the Crustal Deformation of the Eastern Himalayan Syntaxis and Its Adjacent Areas Based on the Earthquake Focal Stress and GPS Strain
作者:
张晨季灵运朱良玉徐晶
(中国地震局第二监测中心,陕西 西安 710054)
Author(s):
ZHANG ChenJI LingyunZHU LiangyuXU Jing
(The Second Monitoring and Application Center,China Earthquake Administration,Xi’an 710054,Shaanxi,China)
关键词:
喜马拉雅东构造结 震源机制解 应力场 GPS应变 地壳形变特征
Keywords:
the Eastern Himalayan Syntaxis focal mechanism solutions stress field GPS strain rate characteristics of the crustal deformation
分类号:
P313.21
DOI:
10.20015/j.cnki.ISSN1000-0666.2022.0051
摘要:
利用1976—2020年喜马拉雅东构造结及邻区ML≥2.0地震的震源机制解反演了研究区域的震源应力场,并结合区域GPS应变率场,分析了该区域现今地壳构造变形特征。结果表明:在川滇菱形块体东边界以及块体内部,最大水平应力SHmax方向与GPS主压应变方向基本一致,且方向变化具有一定的连续性,表明此处上地壳浅部与深部受到相同方向的驱动力; 在川滇菱形块体西边界,最大水平应力方向与GPS主压应变呈现出较明显的差异性,分区均值最大可达42°,表明该处上地壳深浅部可能具有不同的驱动机制。
Abstract:
This paper uses the focal mechanism solutions of ML≥2.0 earthquakes from 1976 to 2020 to invert the focal stress field in the Eastern Himalayan Syntaxis and its surrounding areas,and uses the GPS strain rate field to analyze the current crustal deformation in this area.The results show that on the eastern boundary of the Sichuan-Yunnan block and inside the block,the direction of the maximum horizontal stress changes continuously,almost in the same direction as GPS principal compressive strain; this indicates that the shallow and the deep parts of the upper Crust are driven by forces in the same direction.On the western boundary of the Sichuan-Yunnan block,the direction of the maximum horizontal stress differs sharply from the direction of GPS principal compressive strain,and the regional average can reach up to 42°; this indicates that different driving mechanisms exist in the deep and the shallow of the upper Crust.

参考文献/References:


常利军,王椿镛,丁志峰,等.2015.喜马拉雅东构造结及周边地区上地幔各向异性[J].中国科学:地球科学,45(5):577-588.
崔华伟,万永革,黄骥超,等.2017.2015年3月新不列颠MS7.4地震震源及邻区构造应力场特征[J].地球物理学报,60(3):985-998.
崔效锋,谢富仁.1999.利用震源机制解对中国西南及邻区进行应力分区的初步研究[J].地震学报,21(5):513-522.
郭铁龙,高原.2020.剪切波分裂揭示的青藏高原上地壳地震各向异性基本特征[J].地球物理学报,63(3):1085-1103.
侯强,邹文远,欧明霖,等.2018.青藏高原东南缘壳幔力学耦合及其动力学意义[J].大地测量与地球动力学,38(10):991-1000.
黄臣宇,常利军,丁志峰.2021.喜马拉雅东构造结及周边地区地壳各向异性特征[J].地球物理学报,64(11):3970-3982.
黄骥超,万永革,盛书中,等.2016.汤加—克马德克俯冲带现今非均匀应力场特征及其动力学意义[J].地球物理学报,59(2):578-592.
李君,王勤彩,崔子健,等.2019.川滇菱形块体东边界及邻区震源机制解与构造应力场空间分布特征[J].地震地质,41(6):1395-1412.
王凯悦,常利军,丁志峰.2021.喜马拉雅东构造结上地壳各向异性特征[J].地震学报,43(2):168-179.
王敏,沈正康.2020.中国大陆现今构造变形:三十年的GPS观测与研究[J].中国地震,36(4):660-683.
王晓山,冯向东,赵英萍.2020.京津冀地区地壳应力场特征[J].地震研究,43(4):610-619.
王晓山,吕坚,谢祖军,等.2015.南北地震带震源机制解与构造应力场特征[J].地球物理学报,58(11):4149-4162.
吴微微.2020.安宁河—则木河断裂带及周边地区断层交会部位的应力分布特征[J].地震研究,43(4):601-609.
谢富仁,祝景忠,粱海庆,等.1993.中国西南地区现代构造应力场基本特征[J].地震学报,15(4):407-417.
徐纪人,赵志新,石川有三.2008.中国大陆地壳应力场与构造运动区域特征研究[J].地球物理学报,51(3):770-781.
徐志刚.2017.青藏高原东南缘的地壳应力场及其对壳幔变形的指示[D].南京:南京大学.
杨帆,盛书中,万永革,等.2019.网格内不满足均匀性假设对应力场反演结果的影响——以喜马拉雅东构造结及其周边地区应力场研究为例[J].地球物理学进展,34(2):479-488.
杨建亚,白玲,李国辉,等.2017.东喜马拉雅构造结地区地震活动及其构造意义[J].国际地震动态,(6):12-18.
杨晓松,马瑾.2003.大陆岩石圈解耦及块体运动讨论——以青藏高原—川滇地区为例[J].地学前缘,10(S1):240-247.
张培震,王琪,马宗晋.2002.青藏高原现今构造变形特征与GPS速度场[J].地学前缘,9(2):442-450.
张清志,陈智梁,刘宇平,等.2005.青藏高原及其东南前陆地壳运动的GPS监测[J].地球物理学进展,20(2):524-527.
郑文俊,张培震,袁道阳,等.2009.GPS观测及断裂晚第四纪滑动速率所反映的青藏高原北部变形[J].地球物理学报,52(10):2491-2508.
Aki K,Richards P G.1980.Quantitative seismology:Theory and Methods(Vol.1 and 2)[M].San Francisco:W H Freeman and Co.
Allmendinger R W,Reilinger R,Loveless J.2007.Strain and rotation rate from GPS in Tibet,Anatolia,and the Altiplano[J].Tectonics,26(3):TC3013.1-TC3013.18.
Angelier J.1979.Determination of the mean principal directions of stresses for a given fault population[J].Tectonophysics,56(3-4):T17-T26.
Bilham R,Larson K,Freymueller J.1997.GPS measurements of present-day convergence across the Nepal Himalaya[J].Nature,336(6620):61-64.
Hardebeck J L,Michael A J.2006.Damped regional-scale stress inversions:Methodology and examples for southern California and the Coalinga aftershock sequence[J].Journal of Geophysical Research:Solid Earth,111(B11):310.
Heidbach O,Ben-Avraham Z.2007.Stress evolution and seismic hazard of the Dead Sea Fault System[J].Earth and Planetary Science Letters,257(1-2):299-312.
Lund B,Townend J.2007.Calculating horizontal stress orientations with full or partial knowledge of the tectonic stress tensor[J].Geophysical Journal International,170(3):1328-1335.
Luo Y,Zhao L,Zeng X F,et al.2015.Focal mechanisms of the Lushan earthquake sequence and spatial variation of the stress field[J].Science China(Earth Sciences),58(7):1148-1158.
Martinez-Garzon P,Kwiatek G,Bohnhoff M,et al.2014.MSATSI:A MATLAB package for stress inversion combining solid classic methodology,a new simplified user-handling,and a visualization tool[J].Seismological Research Letters,85(4):896-904.
Pan Z Y,He J K,Shao Z G.2020.Spatial variation in the present-day stress field and tectonic regime of Northeast Tibet from moment tensor solutions of local earthquake data[J].Geophysical Journal International,221(1):478-491.
Pesicek J D,Thurber C H,Widiyantoro S,et al.2010.Sharpening the tomographic image of the subducting slab below Sumatra,the Andaman Islands and Burma[J].Geophysical Journal of the Royal Astronomical Society,182(1):433-453.
Qiu J T,Qiao X J.2017.A study on the seismogenic structure of the 2016 Zaduo,Qinghai MS6.2 earthquake using InSAR technology [J].Geodesy an Geodynamics,8(5):342-346.
Reynolds S D,Mildren S D,Hillis R R,et al.2006.Constraining stress magnitudes using petroleum exploration data in the Cooper-Eromanga Basins,Australia[J].Tectonophysics,415(1-4):123-140.
Shen Z K,Wang M,Zeng Y H,et al.2015.Optimal interpolation of spatially discretized geodetic data[J].Bulletin of the Seismological Society of America,105(4):2117-2127.
Vernant P,Bilham R,Szeliga W,et al.2015.Clockwise rotation of the Brahmaputra Valley relative to India:Tectonic convergence in the eastern Himalaya,Naga Hills,and Shillong Plateau[J].Journal of Geophysical Research Solid Earth,119(8):6558-6571.
Walsh F R,Zoback M D.2016.Probabilistic assessment of potential fault slip related to injection-induced earthquakes:Application to north-central Oklahoma,USA[J].Geology,44(12):991-994.
Wan Y G.2010.Contemporary tectonic stress field in China[J].Acta Seismolo gica Sinca,23(4):377-386.
Wang M,Shen Z K.2020.Present-day crustal deformation of continental China derived from GPS and its tectonic implications[J].Journal of Geophysical Research:Solid Earth,125(2):e2019JB018774.
Zhao L,Luo Y,Liu T Y,et al.2013.Earthquake focal mechanisms in Yunnan and their inference on the regional stress field[J].Bulletin of the Seismological Society of America,103(4):2498-2507.
Zoback M L.1992.First-and second-order patterns of stress in the lithosphere:The world stress map project[J].Journal of Geophysical Research Solid Earth,97(B8):11703-11728.

备注/Memo

备注/Memo:
收稿日期:2021-12-15
基金项目:国家重点研发计划(2017YFC1500501)、国家自然科学基金(42104061)和中国地震局地震科技星火计划项目(XH20083)联合资助.

更新日期/Last Update: 2022-08-01