利用单剖面大地电磁三维反演识别沙德和玉农希断裂

doi:10.3969/j.issn.0253-4967.2019.06.009

摘要/Abstract

摘要： 文中基于实测的单剖面大地电磁数据，研究了沙德和玉农希断裂的深部电性结构，并从识别浅部活动断裂的角度出发，对比了二维模型及不同反演参数下单剖面三维反演模型对已有断裂构造深部结构的分辨能力。研究表明，单剖面数据的二维反演模型与三维模型均能获得合理可靠的区域深部结构特征。综合二维和三维解释模型，在现有的观测数据条件下，文中分析发现沙德断裂和玉农希断裂可能均切割上地壳高阻层，并向深部延伸到中地壳高导层。玉农希断裂在剖面位置近自立（或高角度倾向SE）从地表向深部延伸，沙德断裂的深部倾向为SE。此外，文中的实测资料结果表明，在现有计算能力条件下，三维单剖面反演模型也具有分辨局部断裂构造位置和深部几何结构的能力。最后，文中的工作反映了合适的水平网格间距和模型光滑参数对三维单剖面反演模型结果具有重要影响，过粗的水平网格尺寸和过大的模型水平光滑参数可能会导致三维单剖面反演模型无法正确分辨出浅部断裂构造。而在合理区间调整垂向网格的大小和数据误差门槛，可能对三维单剖面反演模型分辨浅部断裂构造的影响较小。带入倾子的三维单剖面反演能够进一步改善模型对出露地表的断裂构造深部几何结构的约束。

关键词: 大地电磁单剖面数据, 三维反演, 断裂构造识别, 玉农希断裂, 沙德断裂

Abstract: Many synthetic model studies suggested that the best way to obtain good 3D interpretation results is to distribute the MT sites at a 2D grid array with regular site spacing over the target area. However, MT 3D inversion was very difficult about 10 years ago. A lot of MT data were collected along one profile and then interpreted with 2D inversion. How to apply the state-of-the-art 3D inversion technique to interpret the accumulated mass MT profiles data is an important topic. Some studies on 3D inversion of measured MT profile data suggested that 2D inversions usually had higher resolution for the subsurface than 3D inversions. Meanwhile, they often made their interpretation based on 2D inversion results, and 3D inversion results were only used to evaluate whether the overall resistivity structures were correct. Some researchers thought that 3D inversions could not resolute the local structure well, while 2D inversion results could agree with the surface geologic features much well and interpret the geologic structures easily. But in the present paper, we find that the result of 3D inversion is better than that of 2D inversion in identifying the location of the two local faults, the Shade Fault(SDF)and the Yunongxi Fault(YNXF), and the deep structures.
In this paper, we first studied the electrical structure of SDF and YNXF based on a measured magnetotelluric(MT) profile data. Besides, from the point of identifying active faults, we compared the capacity of identifying deep existing faults between 2D inversion models and 3D models with different inversion parameters. The results show that both 2D and 3D inversion of the single-profile data could obtain reasonable and reliable electrical structures on a regional scale. Combining 2D and 3D models, and according to our present data, we find that both SDF and YNXF probably have cut completely the high resistivity layer in the upper crust and extended to the high conductivity layer in the middle crust. In terms of the deep geometry of the faults, at the profile's location, the SDF dips nearly vertically or dips southeast with high dip angle, and the YNXF dips southeast at depth. In addition, according to the results from our measured MT profile, we find that the 3D inversion of single-profile MT data has the capacity of identifying the location and deep geometry of local faults under present computing ability. Finally, this research suggests that appropriate cell size and reasonable smoothing parameters are important factors for the 3D inversion of single-profile MT data, more specifically, too coarse meshes or too large smoothing parameters on horizontal direction of 3D inversion may result in low resolution of 3D inversions that cannot identify the structure of faults. While, for vertical mesh size and data error thresholds, they have limited effect on identifying shallow tectonics as long as their changes are within a reasonable range. 3D inversion results also indicate that, to some extent, adding tippers to the 3D inversion of a MT profile can improve the model's constraint on the deep geometry of the outcropped faults.

Key words: single-profile magnetotelluric data, 3D inversion, faults identification, Yunongxi Fault, Shade Fault

中图分类号:

P315.72⁺1

姜峰, 陈小斌, 董泽义, 崔腾发, 刘钟尹, 王培杰. 利用单剖面大地电磁三维反演识别沙德和玉农希断裂[J]. 地震地质, 2019, 41(6): 1444-1463.

JIANG Feng, CHEN Xiao-bin, DONG Ze-yi, CUI Teng-fa, LIU Zhong-yin, WANG Pei-jie. APPLYING 3D INVERSION OF SINGLE-PROFILE MAGNETOTELLURIC DATA TO IDENTIFY THE SHADE AND YUNONGXI FAULTS[J]. SEISMOLOGY AND GEOLOGY, 2019, 41(6): 1444-1463.

参考文献

蔡军涛, 陈小斌, 赵国泽. 2010. 大地电磁资料精细处理和二维反演解释技术研究(一):阻抗张量分解与构造维性分析［J］. 地球物理学报, 53(10):2516-2526.
CAI Jun-tao, CHEN Xiao-bin, ZHAO Guo-ze. 2010. Refined techniques for data processing and two-dimensional inversion in magnetotelluric I:Tensor decomposition and dimensionality analysis［J］. Chinese Journal of Geophysics, 53(10):2516-2526(in Chinese).
陈小斌, 蔡军涛, 王立凤, 等. 2014. 大地电磁资料精细处理和二维反演解释技术研究(四):阻抗张量分解的多测点-多频点统计成像分析［J］. 地球物理学报, 57(6):1946-1957.
CHEN Xiao-bin, CAI Jun-tao, WANG Li-feng, et al. 2014. Refined techniques for data processing and two-dimensional inversion in magnetotelluric(Ⅳ):Statistical image method based on multi-site, multi-frequency tensor decomposition［J］. Chinese Journal of Geophysics, 57(6):1946-1957(in Chinese).
陈小斌, 郭春玲. 2017. 大地电磁资料精细处理和二维反演解释技术研究(五):利用阻抗张量成像识别大地线性构造［J］. 地球物理学报, 60(2):766-777.
CHEN Xiao-bin, GUO Chun-ling. 2017. Refined techniques for data processing and two-dimensional inversion in magnetotelluric(V):Detecting the linear structures of the earth by impedance tensor imaging［J］. Chinese Journal of Geophysics, 60(2):766-777(in Chinese).
陈小斌, 赵国泽, 詹艳, 等. 2004a. 磁倾子矢量的图示分析及其应用研究［J］. 地学前缘, 11(4):626-636.
CHEN Xiao-bin, ZHAO Guo-ze, ZHAN Yan, et al. 2004a. Analysis of tipper visual vectors and its application［J］. Earth Science Frontiers, 11(4):626-636(in Chinese).
陈小斌, 赵国泽, 马霄. 2006. 大地电磁三维模型的一维二维反演近似问题研究［J］. 工程地球物理学报, 3(1):9-15.
CHEN Xiao-bin, ZHAO Guo-ze, MA Xiao. 2006. Research on inversion of MT 3D model approximately by 1D, 2D inversion method［J］. Chinese Journal of Engineering Geophysics, 3(1):9-15(in Chinese).
陈小斌, 赵国泽, 马霄. 2008. 关于 MT 二维反演中数据旋转方向的选择问题初探［J］. 石油地球物理勘探, 43(1):113-118, 128.
CHEN Xiao-bin, ZHAO Guo-ze, MA Xiao. 2008. Preliminary discussion on selecting rotation direction in 2-D MT inversion［J］. Oil Geophysical Prospecting, 43(1):113-118, 128(in Chinese).
陈小斌, 赵国泽, 詹艳. 2004b. MT资料处理与解释的 Windows 可视化集成系统［J］. 石油地球物理勘探, 39(S1):11-16.
CHEN Xiao-bin, ZHAO Guo-ze, ZHAN Yan. 2004b. A visual integrated windows system for MT data process and interpretation［J］. Oil Geophysical Prospecting, 39(Sl):11-16(in Chinese).
程远志, 汤吉, 蔡军涛, 等. 2017. 青藏高原东缘川滇构造区深部电性结构特征［J］. 地球物理学报, 60(6):2425-2441.
CHENG Yuan-zhi, TANG Ji, CAI Jun-tao, et al. 2017. Deep electrical structure beneath the Sichuan-Yunnan area in the eastern margin of the Tibetan plateau［J］. Chinese Journal of Geophysics, 60(6):2425-2441(in Chinese).
程远志, 汤吉, 陈小斌, 等. 2015. 南北地震带南段川滇黔接壤区电性结构特征和孕震环境［J］. 地球物理学报, 58(11):3965-3981.
CHENG Yuan-zhi, TANG Ji, CHEN Xiao-bin, et al. 2015. Electrical structure and seismogenic environment along the border region of Yunnan, Sichuan and Guizhou in the south of the North-south seismic belt［J］. Chinese Journal of Geophysics, 58(11):3965-3981(in Chinese).
邓起东, 张培震, 冉勇康, 等. 2002. 中国活动构造基本特征［J］. 中国科学(D辑), 32(12):1020-1030.
DENG Qi-dong, ZHANG Pei-zhen, RAN Yong-kang, et al. 2003. Basic characteristics of active tectonics of China［J］. Science in China(Ser D), 46(4):356-372.
董浩, 魏文博, 叶高峰, 等. 2012. 大地电磁测深二维反演方法求解复杂电性结构问题的适应性研究［J］. 地球物理学报, 55(12):4003-4014.
DONG Hao, WEI Wen-bo, YE Gao-feng, et al. 2012. Study of two dimensional magnetotelluric inversions of complex three dimensional structures［J］. Chinese Journal of Geophysics, 55(12):4003-4014(in Chinese).
范文纪. 1982. 贡嘎山的地质构造基础和冰川地貌特征［J］. 成都科技大学学报, (3):19-33.
FAN Wen-ji. 1982. The geological tectonic foundation of Minya Gongga and its characteristic glacial landforms［J］. Journal of Chengdu University of Science and Technology, (3):19-33(in Chinese).
李墩柱, 黄清华, 陈小斌. 2009. 误差对大地电磁测深反演的影响［J］. 地球物理学报, 52(1):268-274.
LI Dun-zhu, HUANG Qing-hua, CHEN Xiao-bin. 2009. Error effects on magnetotelluric inversion［J］. Chinese Journal of Geophysics, 52(1):268-274(in Chinese).
王绪本, 余年, 高嵩, 等. 2017. 青藏高原东缘地壳上地幔电性结构研究进展［J］. 地球物理学报, 60(6):2350-2370.
WANG Xu-ben, YU Nian, GAO Song, et al. 2017. Research progress in research on electrical structure of crust and upper mantle beneath the eastern margin of the Tibetan plateau［J］. Chinese Journal of Geophysics, 60(6):2350-2370(in Chinese).
闻学泽, 白兰香. 1985. 鲜水河活动断裂带形变组合与运动特征的研究［J］. 中国地震, 1(4):55-61.
WEN Xue-ze, BAI Lan-xiang. 1985. Study on the deformation composition and the motion feature of the Xianshuihe active fault zone［J］. Earthquake Research in China, 1(4):55-61(in Chinese).
徐锡伟, 闻学泽, 郑荣章. 2003. 川滇地区活动块体最新构造变动样式及其动力来源［J］. 中国科学(D辑), 33(S1):151-162.
XU Xi-wei, WEN Xue-ze, ZHENG Rong-zhang. 2003. Pattern of latest tectonic motion and its dynamics for active blocks in Sichuan-Yunnan region, China［J］. Science in China(Ser D), 33(S1):151-162(in Chinese).
徐锡伟, 张培震, 闻学泽, 等. 2005. 川西及其邻近地区活动构造基本特征与强震复发模型［J］. 地震地质, 27(3):446-461.
XU Xi-wei, ZHANG Pei-zhen, WEN Xue-ze, et al. 2005. Features of active tectonics and recurrence behaviors of strong earthquakes in the western Sichuan Province and its adjacent regions［J］. Seismology and Geology, 27(3):446-461(in Chinese).
詹艳, 赵国泽, Unsworth M, 等. 2013. 龙门山断裂带西南段4·20芦山7.0级地震区的深部结构和孕震环境［J］. 科学通报, 58(20):1917-1924.
ZHAN Yan, ZHAO Guo-ze, Unsworth M, et al. 2013. Deep structure beneath the southwestern section of the Longmenshan fault zone and seimogenetic context of the 4·20 M_S7.0 earthquake［J］. Chinese Science Bulletin, 58(20):1917-1924(in Chinese).
张建岭, 吴德超, 王道永. 2011. 四川九龙地区八窝龙——玉农希断裂构造变形特征及活动性［J］. 四川地质学报, 31(4):395-398.
ZHANG Jian-ling, WU De-chao, WANG Dao-yong. 2011. Structural deformation and activity of the Bawolung-Yulongxi fracture zone in Jiulong, Sichuan［J］. Acta Geologica Sichuan, 31(4):395-398(in Chinese).
赵国泽, 陈小斌, 王立凤, 等. 2008. 青藏高原东边缘地壳 "管流" 层的电磁探测证据［J］. 科学通报, 53(3):345-350.
ZHAO Guo-ze, CHEN Xiao-bin, WANG Li-feng, et al. 2008. Evidence of crustal ‘channel flow’ in the eastern margin of Tibetan plateau from MT measurements［J］. Chinese Science Bulletin, 53(3):345-350(in Chinese).
赵国泽, 陈小斌, 肖骑彬, 等. 2009. 汶川M_S8.0 级地震成因三 "层次" 分析:基于深部电性结构［J］. 地球物理学报, 52(2):553-563.
ZHAO Guo-ze, CHEN Xiao-bin, XIAO Qi-bin, et al. 2009. Generation mechanism of Wenchuan strong earthquake of M_S8.0 inferred from EM measurements in three levers［J］. Chinese Journal of Geophysics, 52(2):553-563(in Chinese).
赵国泽, 汤吉, 詹艳, 等. 2004. 青藏高原东北缘地壳电性结构和地块变形关系的研究［J］. 中国科学(D辑), 34(10):908-918.
ZHAO Guo-ze, TANG Ji, ZHAN Yan, et al. 2004. Study on the relationship between crustal electrical structure in the northeastern Tibetan and deformation of block［J］. Science in China(Ser D), 34(10):908-918(in Chinese).
赵凌强, 詹艳, 赵国泽, 等. 2015a. 基于深部电性结构特征的 2013 年甘肃岷县漳县M_S6.6 地震孕震环境探讨［J］. 地震地质, 37(2):541-554. doi:10.3969/j.issn.0253-4967.2015.02.016.
ZHAO Ling-qiang, ZHAN Yan, ZHAO Guo-ze, et al. 2015a. The seismogenic environment of the 2013 Minxian-Zhangxian M_S6.6 earthquake based on the deep electrical structure［J］. Seismology and Geology, 37(2):541-554(in Chinese).
赵凌强, 詹艳, 陈小斌, 等. 2015b. 西秦岭造山带(中段)及其两侧地块深部电性结构特征［J］. 地球物理学报, 58(7):2460-2472.
ZHAO Ling-qiang, ZHAN Yan, CHEN Xiao-bin, et al. 2015b. Deep electrical structure of the central West Qinling orogenic belt and blocks on its either side［J］. Chinese Journal of Geophysics, 58(7):2460-2472(in Chinese).
Avdeev D, Avdeeva A. 2009. 3D magnetotelluric inversion using a limited-memory quasi-Newton optimization［J］. Geophysics, 74(3):F45-F57.
Avdeeva A, Avdeev D, Jegen M. 2012. Detecting a salt dome overhang with magnetotellurics:3D inversion methodology and synthetic model studies［J］. Geophysics, 77(4):251-263.
Becken M, Ritter O, Bedrosian P A, et al. 2011. Correlation between deep fluids, tremor and creep along the central San Andreas Fault［J］. Nature, 480(7375):87-90.
Bai D, Unsworth M J, Meju M A, et al. 2010. Crustal deformation of the eastern Tibetan plateau revealed by magnetotelluric imaging［J］. Nature Geoscience, 3(5):358-362. doi:10.1038/ngeo830.
Berdichevsky M, Dmitriev V, Pozdnjakova E. 1998. On two-dimensional interpretation of magnetotelluric soundings［J］. Geophysical Journal International, 133(3):585-606.
Cagniard L. 1953. Basic theory of the magneto-telluric method of geophysical prospecting［J］. Geophysics, 18(3):605-635.
Cai J, Chen X, Xu X, et al. 2017. Rupture mechanism and seismotectonics of the M_S6.5 Ludian earthquake inferred from three-dimensional magnetotelluric imaging［J］. Geophysical Research Letters, 44(3):1275-1285.
Caldwell T G, Bibby H M, Brown C. 2004. The magnetotelluric phase tensor［J］. Geophysical Journal International, 158(2):457-469.
Cordell D, Unsworth M J, Díaz D. 2018. Imaging the Laguna del Maule volcanic field, central Chile using magnetotellurics:Evidence for crustal melt regions laterally-offset from surface vents and lava flows［J］. Earth and Planetary Science Letters, 488:168-180.
Cumming W, Mackie R. 2010. Resistivity imaging of geothermal resources using 1D, 2D and 3D MT inversion and TDEM static shift correction illustrated by a Glass Mountain case history［C］//Proceedings of World Geothermal Congress. Bali, Indonesia:25-29.
Egbert G D. 1997. Robust multiple-station magnetotelluric data processing［J］. Geophysical Journal International, 130(2):475-496.
Egbert G D, Kelbert A. 2012. Computational recipes for electromagnetic inverse problems［J］. Geophysical Journal International, 189(1):251-267.
Gamble T D, Goubau W M, Clarke J. 1979. Magnetotellurics with a remote magnetic reference［J］. Geophysics, 44(1):53-68.
Groom R W, Bailey R C. 1989. Decomposition of magnetotelluric impedance tensors in the presence of local three-dimensional galvanic distortion［J］. Journal of Geophysical Research:Solid Earth, 94(B2):1913-1925.
Heise W, Caldwell T, Bibby H M, et al. 2008. Three-dimensional modelling of magnetotelluric data from the Rotokawa geothermal field, Taupo volcanic zone, New Zealand［J］. Geophysical Journal International, 173(2):740-750.
Kelbert A, Meqbel N, Egbert G D, et al. 2014. ModEM:A modular system for inversion of electromagnetic geophysical data［J］. Computers & Geosciences, 66:40-53.
Ledo J. 2005. 2-D versus 3-D magnetotelluric data interpretation［J］. Surveys in Geophysics, 26(5):511-543.
Lin C H, Tan H D, Shu Q, et al. 2012. Three-dimensional interpretation of sparse survey line MT data:Synthetic examples［J］. Applied Geophysics, 9(1):9-18.
McNeice G W, Jones A G. 2001. Multisite, multifrequency tensor decomposition of magnetotelluric data［J］. Geophysics, 66(1):158-173.
Meqbel N, Weckmann U, Muñoz G, et al. 2016. Crustal metamorphic fluid flux beneath the Dead Sea Basin:Constraints from 2-D and 3-D magnetotelluric modelling［J］. Geophysical Supplements to the Monthly Notices of the Royal Astronomical Society, 207(3):1609-1629.
Miensopust M P. 2017. Application of 3-D electromagnetic inversion in practice:Challenges, pitfalls and solution approaches［J］. Surveys in Geophysics, 38(5):869-933.
Miensopust M P, Queralt P, Jones A G, et al. 2013. Magnetotelluric 3-D inversion:A review of two successful workshops on forward and inversion code testing and comparison［J］. Geophysical Journal International, 193(3):1216-1238.
Patro P K, Egbert G D. 2011. Application of 3D inversion to magnetotelluric profile data from the Deccan Volcanic Province of western India［J］. Physics of the Earth and Planetary Interiors, 187(1-2):33-46.
Rodi W, Mackie R L. 2001. Nonlinear conjugate gradients algorithm for 2-D magnetotelluric inversion［J］. Geophysics, 66(1):174-187.
Siripunvaraporn W, Egbert G. 2009. WSINV3DMT:Vertical magnetic field transfer function inversion and parallel implementation［J］. Physics of the Earth and Planetary Interiors, 173(3-4):317-329.
Siripunvaraporn W, Egbert G, Lenbury Y. 2002. Numerical accuracy of magnetotelluric modeling:A comparison of finite difference approximations［J］. Earth, Planets and Space, 54(6):721-725.
Siripunvaraporn W, Egbert G, Lenbury Y, et al. 2005a. Three-dimensional magnetotelluric inversion:Data-space method［J］. Physics of the Earth and Planetary Interiors, 150(1-3):3-14.
Siripunvaraporn W, Egbert G, Uyeshima M. 2005b. Interpretation of two-dimensional magnetotelluric profile data with three-dimensional inversion:Synthetic examples［J］. Geophysical Journal International, 160(3):804-814.
Su Z, Wang E, Furlong P K, et al. 2012. Young, active conjugate strike-slip deformation in West Sichuan:Evidence for the stress-strain pattern of the southeastern Tibetan plateau［J］. International Geology Review, 54(9):991-1012. doi:10.1080/00206814.2011.583 491.
Tietze K, Ritter O. 2013. Three-dimensional magnetotelluric inversion in practice:The electrical conductivity structure of the San Andreas Fault in central California［J］. Geophysical Journal International, 195(1):130-147.
Tikhonov A. 1950. On determining electric characteristics of the deep layers of the Earth's crust［J］. Doklady Akademii Nauk SSSR, 73(2):295-297.
Tuncer V, Unsworth M J, Siripunvaraporn W, et al. 2006. Exploration for unconformity-type uranium deposits with audiomagnetotelluric data:A case study from the McArthur River mine, Saskatchewan, Canada［J］. Geophysics, 71(6):B201-B209.
Unsworth M, Bedrosian P A. 2004. Electrical resistivity structure at the SAFOD site from magnetotelluric exploration［J］. Geophysical Research Letters, 31(12):L12S05.
Wei W, Unsworth M, Jones A, et al. 2001. Detection of widespread fluids in the Tibetan crust by magnetotelluric studies［J］. Science, 292(5517):716-719.
Xiao Q, Cai X, Xu X, et al. 2010. Application of the 3D magnetotelluric inversion code in a geologically complex area［J］. Geophysical Prospecting, 58(6):1177-1192.
Xiao Q, Shao G, Liu-Zeng J, et al. 2015. Eastern termination of the Altyn Tagh Fault, western China:Constraints from a magnetotelluric survey［J］. Journal of Geophysical Research:Solid Earth, 120(5):2838-2858.
Xiao Q, Yu G, Shao G, et al. 2018. Lateral rheology differences in the lithosphere and dynamics as revealed by magnetotelluric imaging at the northern Tibetan plateau［J］. Journal of Geophysical Research:Solid Earth:123(9):7266-7284.
Xiao Q, Zhao G, Dong Z. 2011. Electrical resistivity structure at the northern margin of the Tibetan plateau and tectonic implications［J］. Journal of Geophysical Research:Solid Earth, 116(B12):B12401.
Zhang H, Huang Q, Zhao G, et al. 2016. Three-dimensional conductivity model of crust and uppermost mantle at the northern Trans North China Orogen:Evidence for a mantle source of Datong volcanoes［J］. Earth and Planetary Science Letters, 453:182-192.
Zhao G, Unsworth M J, Zhan Y, et al. 2012. Crustal structure and rheology of the Longmenshan and Wenchuan M_W7.9 earthquake epicentral area from magnetotelluric data［J］. Geology, 40(12):1139-1142.

[1]	刘钟尹, 陈小斌, 蔡军涛, 崔腾发, 赵国泽, 汤吉, 欧阳飚. 大地电磁三维反演云计算系统toPeak的设计与实现[J]. 地震地质, 2022, 44(3): 802-820.
[2]	吴小平, 汪彤彤. 利用共轭梯度方法的电阻率三维反演若干问题研究[J]. 地震地质, 2001, 23(2): 321-327.