郯庐断裂带鲁苏皖段及邻区构造应力场特征及其动力学意义

doi:10.3969/j.issn.0253-4967.2021.05.010

地震地质 ›› 2021, Vol. 43 ›› Issue (5): 1188-1207.DOI: 10.3969/j.issn.0253-4967.2021.05.010

郯庐断裂带鲁苏皖段及邻区构造应力场特征及其动力学意义

孙业君¹^,²⁾(), 黄耘¹⁾^,^*(), 刘泽民³⁾, 郑建常⁴⁾, 江昊琳¹⁾, 李婷婷¹⁾, 叶青⁵⁾, 方韬⁵⁾

1)江苏省地震局, 南京 210014
2)上海佘山地球物理国家野外科学观测研究站, 上海 201602
3)安徽省地震局, 合肥 230031
4)山东省地震局, 济南 250102
5)上海市地震局, 上海 200062

收稿日期:2020-07-06 修回日期:2021-09-25 出版日期:2021-10-20 发布日期:2021-12-06
通讯作者: 黄耘
作者简介:孙业君, 男, 1979年生, 2015年于东南大学获软件工程专业硕士学位, 高级工程师, 主要从事数字地震学与地震预测等研究工作, E-mail: syj_4116@126.com。
基金资助:
江苏省科技支撑-社会发展项目(BE2016804);上海佘山地球物理国家野外科学观测研究站开放基金(SSOP202109);中国地震局地震科技星火计划项目(XH15020Y);中国地震局地震科技星火计划项目(XH19014)

CHARACTERISTICS OF TECTONIC STRESS FIELD AND DYNAMIC SIGNIFICANCE IN THE SHANDONG-JIANGSU-ANHUI SEGMENT OF TANCHENG-LUJIANG FAULT ZONE AND ITS ADJACENT AREAS

SUN Ye-jun¹^,²⁾(), HUANG Yun¹⁾^,^*(), LIU Ze-min³⁾, ZHENG Jian-chang⁴⁾, JIANG Hao-lin¹⁾, LI Ting-ting¹⁾, YE Qing⁵⁾, FANG Tao⁵⁾

1) Jiangsu Earthquake Agency, Nanjing 210014, China
2) Shanghai Sheshan National Geophysical Observatory and Research Station, Shanghai 201602, China
3) Anhui Earthquake Agency, Hefei 230031, China
4) Shandong Earthquake Agency, Jinan 250102, China
5) Shanghai Earthquake Agency, Shanghai 200062, China

Received:2020-07-06 Revised:2021-09-25 Online:2021-10-20 Published:2021-12-06
Contact: HUANG Yun

摘要/Abstract

摘要：

文中利用区域台网数字地震波形, 计算了2001—2016年郯庐断裂带鲁苏皖段及邻区825次中小地震的震源机制解, 并收集了1970—2000年模拟记录时期323个震源机制解, 共计获得1 148个震源机制解。以震源机制解作为输入数据, 采用阻尼应力张量方法反演获得了研究区1.0°×1.0°空间应力场变化特征。结果显示, 郯庐断裂带鲁苏皖段最大主应力方向呈现空间连续性变化特征, 由西向东总体呈EW、 NEE、 NE向逆时针趋势性旋转, 局部存在差异; 以郯庐断裂带为界, 东、西两侧的应力场存在差异, 以西的华北平原地块最大主应力方向主要表现为近EW向和NEE向, 而以东的鲁东-黄海地块则表现为NEE向和NE向, 反映了W向倾斜延伸至上地幔顶部的郯庐断裂带使得各动力源对不同块体的影响存在差异, 显示了郯庐断裂带的边界作用显著; 沿郯庐断裂带33°N为界, 南、北地区的应力场存在显著差异, 33°N及以北地区最大主应力方向由西向东出现逆时针偏转, 而以南地区最大主应力方向由西向东开始出现顺时针偏转的迹象; (31°~33°N, 120°~122°E)区域的最大主应力方向较为复杂, 呈放射状分布特征, 该区域处于非常复杂的构造环境下, 可能受到华北平原地块近EW—NEE向运动导致的郯庐断裂带右旋走滑作用和菲律宾海板块W向俯冲的共同影响; 研究区的中强地震活动与构造应力环境相关明显, 构造应力场复杂的地区往往是中强地震活跃的地区。

关键词: 震源机制, 应力场, 动力学, 郯庐断裂带鲁苏皖段

Abstract:

The Shandong-Jiangsu-Anhui segment of Tancheng-Lujiang fault zone is a key seismic monitoring and defense area in China due to its complex structural deformation and intense seismic activity. With the accumulation of digital seismic data from the digital seismic networks of provinces and cities in the area and its adjacent regions, the waveform quality is steadily advanced, and the calculation methods for the focal mechanism solution and the inversion methods of stress field are constantly improved, which makes it possible to obtain more reliable focal mechanism solution and more accurate stress field.
Based on the seismic waveform data recorded by regional seismic network, we calculated and obtained focal mechanism solutions of 825 moderate and small earthquakes in Shandong-Jiangsu-Anhui segment of Tancheng-Lujiang fault zone and its adjacent areas from 2001 to 2016, by using the initial motion and amplitude information of P wave, SH wave and SV wave. In addition, we collected focal mechanism solutions of 323 earthquakes from 1970 to 2000. A total of 1 148 focal mechanism solutions were obtained. With the focal mechanism solutions as the input data, we adopted the damped regional-scale stress method to inverse and calculate the spatial variation characteristics of the stress field by 1.0°×1.0°grid region of the study area, and discussed the structural boundary, block difference, stress environment, seismicity and related dynamic problems. The results show that the maximum principal stress direction of the study area presents continuous change spatially, with an overall rotation trend in EW, NEE and NE direction from west to east, and there are differences locally. The dominant stress type is strike-slip, followed by normal strike-slip, indicating that the study area is generally under the action of horizontal stress field, and the difference of stress types mainly reflects the difference of local geological tectonic environment and fault activity mode to a certain extent.
Taking the Tancheng-Lujiang fault zone as the boundary, the stress fields of the Ludong-Yellow Sea block and the North China Plain on the both sides are different. The direction of maximum principal stress in the North China Plain block on the west is near-EW and NEE, while that on the east is NEE and NE. The analysis shows that the near EW-directed stress field in the North China Plain block generally inherits the stress field pattern resulting from the eastward extrusion of the Qinghai-Tibet block, but is more influenced by the near EW compression of the Qinghai-Tibet block. The stress field of the Ludong-Yellow Sea block is obviously affected by the westward subduction of the Philippine Sea plate. Although the whole North China block is controlled by the combined action of the northward push of the Indian plate and the westward subduction of the Philippine Sea plate, the effects of various driving forces on different secondary blocks in the block are different due to the existence of the Tancheng-Lujiang fault zone which extends obliquely to the top of the upper mantle. It reflects significantly that the Tancheng-Lujiang fault zone plays a significant role as a block boundary fault.
Along the 33°N latitude of Tancheng-Lujiang fault zone, there is a significant difference in the stress field between the north and the south. The direction of the maximum principal stress at the 33°N and its north area begins to deflect anticlockwise from west to east; while in 32°N and to the south, it is deflected clockwise from west to east. The direction of the maximum principal stress gradually transits from NE in North China to NW in South China, showing the characteristics of the stress field in South China to some extent. It indicates that 31°~32°N latitude is the transition zone of the two primary blocks, the North China block and the South China block. The direction of the maximum principal stress of the area between 31°~33°N and 120°~122°E is complex and characterized by radial distribution. This region locates in a very complex tectonic environment and may be influenced by the dextral strike-slip of Tancheng-Lujiang Fault caused by the near EW—NEE movement of the North China Plain block as well as the westward subduction of the Philippine Sea plate. The moderate-strong seismicity in the study area is obviously related to the tectonic stress environment. The area with complex tectonic stress field is usually the area with moderate-strong earthquake activity.

Key words: focal- mechanism, stress field, dynamics, Shandong-Jiangsu-Anhui segment of Tancheng-Lujiang fault zone

中图分类号:

P315.2

孙业君, 黄耘, 刘泽民, 郑建常, 江昊琳, 李婷婷, 叶青, 方韬. 郯庐断裂带鲁苏皖段及邻区构造应力场特征及其动力学意义[J]. 地震地质, 2021, 43(5): 1188-1207.

SUN Ye-jun, HUANG Yun, LIU Ze-min, ZHENG Jian-chang, JIANG Hao-lin, LI Ting-ting, YE Qing, FANG Tao. CHARACTERISTICS OF TECTONIC STRESS FIELD AND DYNAMIC SIGNIFICANCE IN THE SHANDONG-JIANGSU-ANHUI SEGMENT OF TANCHENG-LUJIANG FAULT ZONE AND ITS ADJACENT AREAS[J]. SEISMOLOGY AND EGOLOGY, 2021, 43(5): 1188-1207.

图/表 8

参考文献 50

[1]	晁洪太, 李家灵, 崔昭文, 等. 1994. 郯庐断裂带中段全新世活断层的特征滑动行为与特征地震[J]. 内陆地震, 8(4): 297-304.
	CHAO Hong-tai, LI Jia-ling, CUI Zhao-wen, et al. 1994. Characteristic slip behavior of the Holocene fault in the central section of the Tanlu fault zone and the characteristic earthquakes[J]. Inland Earthquake, 8(4): 297-304. (in Chinese)
[2]	邓起东, 张裕明, 许桂林, 等. 1979. 中国构造应力场特征及其与板块运动的关系[J]. 地震地质, 1(1): 11-22.
	DENG Qi-dong, ZHANG Yu-ming, XU Gui-lin, et al. 1979. On the tectonic stress field in China and its relation to plate movement[J]. Seismology and Geology, 1(1): 11-22. (in Chinese)
[3]	杜兴信, 邵辉成. 1999. 由震源机制解反演中国大陆现代构造应力场[J]. 地震学报, 21(4): 354-360.
	DU Xing-xin, SHAO Hui-cheng. 1999. Modern tectonic stress field in the Chinese mainland inversed from focal mechanism solutions[J]. Acta Seismologica Sinica, 21(4): 354-360. (in Chinese)
[4]	李家灵, 晁洪太. 1994. 郯庐活断层的分段及其大震危险性分析[J]. 地震地质, 16(2): 121-126.
	LI Jia-ling, CHAO Hong-tai. 1994. Segmentation of active fault along the Tancheng-Lujiang fault zone and evaluation of strong earthquake risk[J]. Seismology and Geology, 16(2): 121-126. (in Chinese)
[5]	李延兴, 杨国华, 李智, 等. 2003. 中国大陆活动地块的运动与应变状态[J]. 中国科学(D辑), 33(S1): 65-81.
	LI Yan-xing, YANG Guo-hua, LI Zhi, et al. 2003. Movement and strain conditions of active blocks in the Chinese mainland[J]. Science in China(Ser D), 33(S1): 65-81. (in Chinese)
[6]	刘东旺, 夏瑞良, 刘泽民, 等. 2006. 郯庐断裂带安徽段现代地震活动及应力场特征[J]. 地质科学, 41(2): 278-290.
	LIU Dong-wang, XIA Rui-liang, LIU Ze-min, et al. 2006. Characteristics of recent seismicity and stress fields in Anhui sector of the Tan-Lu fault zone[J]. Chinese Journal of Geology, 41(2): 278-290. (in Chinese)
[7]	刘杰, 郑斯华, 康英, 等. 2004. 利用P波和S波的初动和振幅比计算中小地震的震源机制解[J]. 地震, 24(1): 19-26.
	LIU Jie, ZHENG Si-hua, KANG Ying, et al. 2004. The focal mechanism determinations of moderate-small earthquakes using the first motion and amplitude ratio of P and S wave[J]. Earthquake, 24(1): 19-26. (in Chinese)
[8]	刘泽民, 刘东旺, 李玲利, 等. 2011. 利用多个震源机制解求东大别地区平均应力场[J]. 地震学报, 33(5): 605-613.
	LIU Ze-min, LIU Dong-wang, LI Ling-li, et al. 2011. Determination of mean stress field in eastern Dabie region from focal mechanism solution analysis[J]. Acta Seismologica Sinica, 33(5): 605-613. (in Chinese)
[9]	罗艳, 赵里, 曾祥方, 等. 2015. 芦山地震序列震源机制及其构造应力场空间变化[J]. 中国科学(D辑), 45(4): 538-550.
	LUO Yan, ZHAO Li, ZENG Xiang-fang, et al. 2015. Focal mechanisms of the Lushan earthquake sequence and spatial variation of the stress field[J]. Science in China(Ser D), 45(4): 538-550. (in Chinese)
[10]	马杏垣. 1987. 中国岩石圈动力学概要[J]. 地质学报, 61(2): 113-125.
	MA Xing-yuan. 1987. Summary of the lithospheric dynamics in China[J]. Acta Geologica Sinica, 61(2): 113-125. (in Chinese)
[11]	倪红玉, 刘泽民, 何康. 2013. 郯庐断裂带安徽段中小地震震源机制及现代应力场特征[J]. 地震工程学报, 35(3): 677-683.
	NI Hong-yu, LIU Ze-min, HE Kang. 2013. Study on focal mechanisms of moderate-small earthquakes and characteristics of recent tectonic stress field in the Anhui sector of Tanlu fault zone[J]. China Earthquake Engineering Journal, 35(3): 677-683. (in Chinese)
[12]	孙长虹, 许丰, 杨玉波, 等. 2012. 2003年青海德令哈6.7级地震序列的震源机制解及其构造含义[J]. 地球物理学报, 55(10): 3338-3346.
	SUN Chang-hong, XU Feng, YANG Yu-bo, et al. 2012. Focal mechanism solutions of 2003 Delingha, Qinghai, M 6.7 earthquake sequence and its tectonic implication[J]. Chinese Journal of Geophysics, 55(10): 3338-3346. (in Chinese)
[13]	孙业君, 黄耘, 江昊琳, 等. 2015. 郯庐断裂带鲁苏皖段构造应力场及分段特征研究[J]. 地震, 35(3): 66-75.
	SUN Ye-jun, HUANG Yun, JIANG Hao-lin, et al. 2015. Tectonic stress field and segmentation characteristics in the Shandong-Jiangsu-Anhui segment of the Tancheng-Lujiang fault zone[J]. Earthquake, 35(3): 66-75. (in Chinese)
[14]	孙业君, 赵小艳, 黄耘, 等. 2017. 云南地区震源机制及应力场特征[J]. 地震地质, 39(2): 390-407. doi: 10.3969/j.issn.0253-4967.2017.02.009. DOI
	SUN Ye-jun, ZHAO Xiao-yan, HUANG Yun, et al. 2017. Characteristics of focal mechanisms and stress field of Yunnan area[J]. Seismology and Geology, 39(2): 390-407. (in Chinese)
[15]	滕吉文, 闫雅芬, 王光杰, 等. 2006. 大别造山带与郯庐断裂带壳、幔结构和陆内 “俯冲”的耦合效应[J]. 地球物理学报, 49(2): 449-457.
	TENG Ji-wen, YAN Ya-fen, WANG Guang-jie, et al. 2006. Structure of Earth’s crust and upper mantle, inland subduction and its coupling effects on the Dabie orogenic belt and the Tancheng-Lujiang fault zone[J]. Chinese Journal of Geophysics, 49(2): 449-457. (in Chinese)
[16]	万桂梅, 汤良杰, 金文正, 等. 2009. 郯庐断裂带研究进展及存在问题探讨[J]. 地质论评, 55(2): 251-259.
	WAN Gui-mei, TANG Liang-jie, JIN Wen-zheng, et al. 2009. Progresses and problems in the study of Tancheng-Lujiang fault zone[J]. Geological Review, 55(2): 251-259. (in Chinese)
[17]	万永革, 盛书中, 许雅儒, 等. 2011. 不同应力状态和摩擦系数对综合P波辐射花样影响的模拟研究[J]. 地球物理学报, 54(4): 994-1001. doi: 10.3969/j.issn.000a-5733.2011.04.014. DOI
	WAN Yong-ge, SHENG Shu-zhong, XU Ya-ru, et al. 2011. Effect of stress ratio and friction coefficient on composite P wave radiation patterns[J]. Chinese Journal of Geophysics, 54(4): 994-1001. (in Chinese)
[18]	汪素云, 许忠淮, 俞言祥, 等. 1996. 中国及其邻区周围板块作用力的研究[J]. 地球物理学报, 39(6): 764-771.
	WANG Su-yun, XU Zhong-huai, YU Yan-xiang, et al. 1996. Inversion for the plate driving forces acting at the boundaries of China and its surroundings[J]. Chinese Journal of Geophysics, 39(6): 764-771. (in Chinese)
[19]	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.
	WANG Xiao-shan, LÜ Jian, XIE Zu-jun, et al. 2015. Focal mechanisms and tectonic stress field in the North-South Seismic Belt of China[J]. Chinese Journal of Geophysics, 58(11): 4149-4162. (in Chinese)
[20]	谢富仁, 崔效锋, 赵建涛, 等. 2004. 中国大陆及邻区现代构造应力场分区[J]. 地球物理学报, 47(4): 654-662. doi: 10.3321/j.issn:0001-5733.2004.04.016. DOI
	XIE Fu-ren, CUI Xiao-feng, ZHAO Jian-tao, et al. 2004. Regional division of the recent tectonic stress field in China and adjacent areas[J]. Chinese Journal of Geophysics, 47(4): 654-662. (in Chinese)
[21]	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.
	U Ji-ren, ZHAO Zhi-xin, Ishikawa Y. 2008. Regional characteristics of crustal stress field and tectonic motions in and around Chinese mainland[J]. Chinese Journal of Geophysics, 51(3): 770-781. (in Chinese)
[22]	徐鸣洁, 姜永基, 周翠英. 1996. 江苏及邻区现代应力场空间分布特征分析[J]. 中国地震, 12(4): 383-388.
	XU Ming-jie, JIANG Yong-ji, ZHOU Cui-ying. 1996. Preliminary analysis for the space distribution of present stress field in Jiangsu and its adjacent area[J]. Earthquake Research in China, 12(4): 383-388. (in Chinese)
[23]	许忠淮. 2001. 东亚地区现今构造应力图的编制[J]. 地震学报, 23(5): 492-501. doi: 10.3321/j.issn:0253-3782.2001.05.005. DOI
	XU Zhong-huai. 2001. A present-day tectonic stress map for eastern Asia region[J]. Acta Seismologica Sinica, 23(5): 492-501. (in Chinese)
[24]	许忠淮, 汪素云, 黄雨蕊, 等. 1989. 由大量的地震资料推断的中国大陆构造应力场[J]. 地球物理学报, 32(6): 636-647.
	XU Zhong-huai, WANG Su-yun, HUANG Yu-rui, et al. 1989. The tectonic stress field of Chinese continent deduced from a great number of earthquakes[J]. Chinese Journal of Geophysics, 32(6): 636-647. (in Chinese)
[25]	杨佳佳, 张永庆, 谢富仁. 2018. 日本海沟俯冲带M_W9.0地震震源区应力场演化分析[J]. 地球物理学报, 61(4): 1307-1324. doi: 10.6038/cjg2018L0258. DOI
	YANG Jia-jia, ZHANG Yong-qing, XIE Fu-ren. 2018. The evolutionary analysis of the stress field in the seismic focal zone of the great Tohoku-Oki earthquake(M_W=9.0)in the Japan trench subduction zone[J]. Chinese Journal of Geophysics, 61(4): 1307-1324. (in Chinese)
[26]	张东宁, 许忠淮. 1999. 中国大陆岩石层动力学数值模型的边界条件[J]. 地震学报, 21(2): 133-199.
	ZHANG Dong-ning,. XU Zhong-huai. 1999. Boundary condition of the dynamic numerical model for Mainland China lithosphere[J]. Acta Seismologica Sinica, 21(2): 133-199. (in Chinese)
[27]	张继红, 赵国泽, 肖骑彬, 等. 2010. 郯庐断裂带中段(沂沭断裂带)电性结构研究与孕震环境[J]. 地球物理学报, 53(3): 605-611. doi: 10.3969/j.issn.0001-5733.2010.03.014. DOI
	ZHANG Ji-hong, ZHAO Guo-ze, XIAO Qi-bin, et al. 2010. Analysis of electric structure of the central Tan-Lu fault zone(Yi-Shu fault zone, 36°N)and seismogenic condition[J]. Chinese Journal of Geophysics, 53(3): 605-611. (in Chinese)
[28]	张培震, 邓起东, 张国民, 等. 2003. 中国大陆的强震活动与活动地块[J]. 中国科学(D辑), 33(S1): 12-20.
	ZHANG Pei-zhen, DENG Qi-dong, ZHANG Guo-min, et al. 2003. Active tectonic blocks and strong earthquake in the continent of China[J]. Science in China(Ser D), 33(S1): 12-20.
[29]	张培震, 王琪, 马宗晋. 2002. 中国大陆现今构造运动的GPS速度场与活动地块[J]. 地学前缘, 9(2): 430-441.
	ZHANG Pei-zhen, WANG Qi, MA Zong-jin. 2002. GPS velocity field and active crustal blocks of contemporary tectonic deformation in continental China[J]. Earth Science Frontiers, 9(2): 430-441. (in Chinese)
[30]	张绍治, 吴少武, 刘仲方. 1989. 郯庐断裂带中南段现代构造应力场[J]. 地震, 9(4): 65-77.
	ZHANG Shao-zhi, WU Shao-wu, LIU Zhong-fang. 1989. Recent tectonic stress field in middle-south segment of Tanlu fault zone[J]. Earthquake, 9(4): 65-77. (in Chinese)
[31]	张文佑, 李阴槐, 张弛, 等. 1986. 中国及邻区海陆大地构造[M]. 北京: 科学出版社: 267-278.
	ZHANG Wen-you, LI Yin-huai, ZHANG Chi, et al. 1986. Marine and Continental Geotectonics of China and Its Environs[M]. Science Press, Beijing: 267-278. (in Chinese)
[32]	赵朋, 姚大全, 杨源源, 等. 2017. 郯庐断裂带大红山段晚第四纪以来的新活动[J]. 地震地质, 39(3): 550-560. doi: 10.3969/j.issn.0253-4967.2017.03.008. DOI
	ZHAO Peng, YAO Da-quan, YANG Yuan-yuan, et al. 2017. The new activity of Tan-Lu fault zone in segment of Dahongshan since late Quaternary[J]. Seismology and Geology, 39(3): 550-560. (in Chinese)
[33]	郑建常, 王鹏, 李冬梅, 等. 2013. 使用小震震源机制解研究山东地区背景应力场[J]. 地震学报, 35(6): 773-784.
	ZHENG Jian-chang, WANG Peng, LI Dong-mei, et al. 2013. Tectonic stress field in Shandong region inferred from small earthquake focal mechanism solutions[J]. Acta Seismologica Sinica, 35(6): 773-784. (in Chinese)
[34]	周翠英, 王铮铮, 蒋海昆, 等. 2005. 华东地区现代地壳应力场及地震断层错动性质[J]. 地震地质, 27(2): 273-288.
	ZHOU Cui-ying, WANG Zheng-zheng, JIANG Hai-kun, et al. 2005. Contemporary crustal stress field and feature of earthquake fault slip in East China[J]. Seismology and Geology, 27(2): 273-288. (in Chinese)
[35]	朱光, 徐佑德, 刘国生, 等. 2006. 郯庐断裂带中-南段走滑构造特征与变形规律[J]. 地质科学, 41(2): 226-241.
	ZHU Guang, XU You-de, LIU Guo-sheng, et al. 2006. Structural and deformational characteristics of strike-slippings along the middle-southern sector of the Tan-Lu fault zone[J]. Chinese Journal of Geology, 41(2): 226-241.
[36]	Guiraud M, Laborde O, Philip H. 1989. Characterization of various types of deformation and their corresponding deviatoric stress tensors using microfault analysis[J]. Tectonophysics, 170(3-4): 289-316. DOI URL
[37]	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): 1-11.
[38]	Heidbach O, Tingay M, Barth A, et al. 2010. Global crustal stress pattern based on the World Stress Map database release 2008 [J]. Tectonophysics, 482(1-4): 3-15. DOI URL
[39]	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. DOI URL
[40]	Martínez-Garzón 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. DOI URL
[41]	Michael A J. 1984. Determination of stress from slip data: Faults and folds[J]. Journal of Geophysical Research: Solid Earth, 89(B13): 11517-11526.
[42]	Michael A J. 1987. Use of focal mechanisms to determine stress: A control study[J]. Journal of Geophysical Research: Solid Earth, 92(B1): 357-368.
[43]	Snoke J A. 1989. Earthquake mechanism[G]//James D E. Encyclopedia of Geophysics. New York: Van Nostrand Reinhold Company: 239-245.
[44]	Snoke J A, Munsey J W, Teague A G, et al. 1984. A program for focal mechanism determination by combined use of polarity and SV2P amplitude ratio data[J]. Earthquake Notes, 55(3): 15-20.
[45]	Wan Y G. 2010. Contemporary tectonic stress field in China[J]. Earthquake Science, 23(4): 377-386. DOI URL
[46]	Wan Y G, Sheng S Z, Huang J C, et al. 2016. The grid search algorithm of tectonic stress tensor based on focal mechanism data and its application in the boundary zone of China, Vietnam and Laos[J]. Journal of Earth Science, 27(5): 777-785. DOI URL
[47]	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, 125(2): 1-22.
[48]	Zhang Y G, Zheng W J, Wang Y J, et al. 2018. Contemporary deformation of the North China plain from Global Positioning System data[J]. Geophysical Research Letters, 45(4): 1851-1859. DOI URL
[49]	Zhao L, Lou 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. DOI URL
[50]	Zoback M L. 1992. First- and second-order patterns of stress in the lithosphere: The world stress map project[J]. Journal of Geophysical Research, 97(B8): 11703-11728. DOI URL

序号	网格节点		σ₁轴		σ₂轴		σ₃轴		R值	应力类型	震源机制解数目
	东经/(°)	北纬/(°)	方位角/(°)	倾伏角/(°)	方位角/(°)	倾伏角/(°)	方位角/(°)	倾伏角/(°)
1	115	30	95.23 34.30~174.70	2.77 -77.40~84.90	-18.15 -197.60~160.30	83.05 1.20~89.20	-174.46 -206.10~-39.20	6.37 -68.90~81.60	0.52 0.02~0.99	走滑	19
2	115	31	-82.51 -149.00~64.90	7.29 -81.60~88.80	36.37 -143.60~215.50	75.16 -13.20~89.00	-174.18 -198.70~-153.20	12.86 -76.60~63.30	0.62 0.03~0.99	走滑	8
3	115	32	90.54 -67.70~225.10	15.56 -61.20~88.80	-58.93 -233.30~120.60	72.09 -12.90~89.40	-177.03 -223.40~-97.70	8.66 -53.30~72.40	0.47 0.01~0.98	走滑	30
4	115	33	92.92 72.10~111.00	16.30 -19.40~53.00	-132.70 -301.00~33.30	67.31 10.40~88.40	-1.68 -60.60~21.60	15.34 -44.90~71.50	0.49 0.05~0.97	走滑	9
5	115	34	-89.94 -262.60~71.20	5.64 -83.10~88.60	133.70 -45.70~312.90	82.23 -6.70~89.50	0.59 -30.50~40.30	5.32 -49.90~58.30	0.65 0.07~1.00	走滑	8
6	115	35	-107.47 -123.00~-93.30	4.68 -31.60~36.00	-1.49 -180.90~177.40	73.44 8.10~89.60	161.20 109.00~175.70	15.84 -35.50~77.70	0.46 0.04~0.98	走滑	11
7	115	36	102.20 71.50~129.40	17.74 -41.60~54.70	-21.80 -192.60~158.20	60.23 -23.00~89.20	-159.96 -198.50~-6.40	23.08 -59.20~84.50	0.37 0.02~0.90	走滑	45
8	116	30	-85.55 -106.00~0	7.05 -21.00~42.10	40.05 -137.00~215.50	78.01 -7.60~89.40	-176.76 -325.80~-78.40	9.65 -78.80~87.40	0.32 0.01~0.87	走滑	18
9	116	31	-85.42 -97.80~0	6.73 -19.30~35.70	121.26 -58.20~299.00	82.48 54.80~89.60	4.97 -7.50~13.70	3.35 -45.00~21.90	0.57 0.30~0.87	走滑	101
10	116	32	-86.05 -97.90~0	1.86 -23.90~23.90	175.83 -4.10~350.00	77.07 60.50~89.60	4.37 -9.80~9.60	12.79 -45.00~25.50	0.52 0.24~0.87	走滑	78
11	116	33	91.83 77.70~105.20	8.46 -6.90~26.30	-151.27 -275.10~4.10	71.81 47.00~88.50	-0.61 -15.00~15.60	15.99 -44.80~42.20	0.39 0.11~0.75	走滑	14
12	116	34	-93.70 -112.70~-52.20	8.35 -70.90~68.10	142.03 -23.20~322.00	75.38 15.50~89.70	-1.93 -16.50~11.40	11.91 -45.00~37.20	0.66 0.21~0.98	走滑	5
13	116	35	-101.24 -116.70~-86.30	14.13 -8.10~42.30	39.41 -75.90~217.90	71.96 -10.90~89.30	165.96 38.60~187.90	10.97 -55.60~81.30	0.41 0.02~0.87	走滑	6
14	116	36	95.01 -58.80~221.50	6.74 -82.70~89.20	-69.19 -249.00~110.80	83.00 -5.80~89.60	-174.77 -230.00~-109.30	1.89 -80.40~81.20	0.52 0.02~0.99	走滑	9
15	117	30	-87.49 -104.00~0	10.07 -14.60~28.90	39.63 -140.00~219.10	73.61 -11.00~89.50	-179.80 -338.00~-118.60	12.80 -67.60~88.00	0.28 0.01~0.70	走滑	6
16	117	31	88.27 73.50~100.20	10.43 -14.90~29.30	-155.06 -209.60~-9.90	67.70 -14.00~87.70	-5.46 -146.50~26.20	19.48 -57.20~78.50	0.31 0.02~0.69	走滑	44
17	117	32	93.42 77.80~180.00	2.02 -21.00~23.30	-170.40 -349.80~9.00	71.89 12.10~89.20	2.77 -25.50~15.50	17.99 -69.00~76.60	0.35 0.03~0.73	走滑	32
18	117	33	-90.96 -105.40~-77.80	2.75 -32.90~35.10	101.38 -78.60~281.30	87.18 53.90~90.00	-0.94 -17.60~12.50	0.60 -45.00~33.30	0.48 0.11~0.91	走滑	35
19	117	34	-101.27 -114.20~-91.10	17.07 -4.90~34.70	98.12 -1.80~200.90	71.96 48.60~86.90	-9.54 -24.20~3.50	5.64 -44.20~32.20	0.44 0.15~0.74	走滑	13
20	117	35	-100.46 -110.00~-88.40	17.28 -2.50~34.50	73.38 -39.00~191.70	72.63 5.00~89.80	168.99 99.70~224.80	1.75 -70.80~66.90	0.36 0~0.75	走滑	16
21	117	36	87.73 -91.50~267.70	46.88 -42.60~88.50	-91.16 -268.80~88.80	43.11 -45.80~89.10	178.33 147.10~211.10	0.55 -38.90~45.00	0.69 0.14~0.98	正走滑	13
22	118	31	78.68 35.80~118.30	2.29 -48.50~49.60	172.22 0.70~350.40	57.04 -31.60~88.00	-12.81 -190.70~126.10	32.86 -55.30~81.40	0.46 0.01~0.98	走滑	27
23	118	32	-104.15 -119.80~-93.40	3.47 -17.90~23.10	153.88 -25.60~333.80	73.69 -16.00~89.70	-13.16 -43.30~149.40	15.92 -71.50~86.30	0.30 0.01~0.73	走滑	28
24	118	33	-95.62 -107.50~-88.70	17.37 -2.60~41.80	97.86 10.50~195.30	72.17 47.60~88.50	-4.39 -22.10~4.30	3.90 -44.80~25.10	0.50 0.21~0.78	走滑	12
25	118	34	-102.39 -113.20~-92.10	22.50 8.40~30.30	118.81 19.90~156.60	61.17 43.70~78.20	-5.09 -33.70~6.40	17.07 -43.40~39.20	0.31 0.04~0.57	正走滑	19
26	118	35	-101.41 -111.00~-90.90	7.74 -9.30~19.90	57.53 -121.30~236.10	81.72 6.10~89.80	168.19 110.80~186.20	2.94 -66.00~78.80	0.34 0~0.67	走滑	20
27	118	36	75.77 -75.70~94.40	13.17 -43.00~77.10	-59.69 -228.80~118.00	71.82 -11.80~89.30	168.70 157.00~183.80	12.30 -10.40~45.00	0.62 0.22~0.96	走滑	22
28	118	37	85.56 -69.70~264.40	43.33 -44.20~89.50	-104.75 -284.70~74.20	46.21 -42.50~89.40	-9.34 -23.70~18.00	5.17 -45.00~20.40	0.71 0.29~0.98	正走滑	11
29	119	31	-97.55 -116.50~-74.40	1.77 -73.80~52.90	155.65 -24.00~335.40	83.89 14.90~89.90	-7.37 -22.30~7.20	5.85 -45.00~31.70	0.59 0.14~0.98	走滑	36
30	119	32	-95.42 -123.10~-81.50	4.79 -39.10~53.00	160.98 -12.10~340.30	70.39 30.70~89.20	-3.76 -23.70~12.00	18.97 -45.00~47.80	0.53 0.13~0.94	走滑	37
31	119	33	-109.72 -123.10~-47.70	3.12 -70.50~81.70	28.70 -149.70~208.40	85.84 3.40~89.80	160.13 151.70~169.30	2.76 -11.00~44.20	0.72 0.44~0.98	走滑	31
32	119	34	-109.02 -288.20~55.80	6.93 -82.70~87.80	59.28 -120.60~239.20	82.93 -6.70~89.60	160.81 148.60~172.50	1.42 -10.50~44.30	0.91 0.51~0.99	走滑	8
33	119	35	-99.31 -277.10~77.40	34.73 -53.00~87.20	68.72 -108.70~244.00	54.68 -31.70~89.00	166.75 148.50~186.60	5.66 -15.30~44.80	0.71 0.25~0.99	正走滑	27
34	119	36	76.52 -99.50~227.80	16.53 -72.20~82.20	-125.24 -303.40~50.60	72.28 -13.30~89.70	-15.33 -27.50~-0.20	6.21 -45.00~24.30	0.65 0.30~0.97	走滑	24
35	120	31	98.69 -80.70~277.70	15.69 -69.30~87.20	-59.29 -239.00~120.50	73.14 -15.00~89.40	-169.62 -306.80~-4.70	6.01 -69.50~84.20	0.41 0.02~0.98	走滑	18
36	120	32	86.26 6.40~242.40	15.00 -74.60~84.90	-102.95 -282.10~76.70	74.81 -14.50~89.50	-4.36 -99.10~77.90	2.32 -84.70~85.50	0.41 0~0.99	走滑	29
37	120	33	-109.84 -120.10~-101.40	12.35 -11.30~32.20	37.54 -139.70~216.70	75.43 57.00~89.50	158.48 148.50~168.10	7.61 -8.70~43.80	0.61 0.31~0.84	走滑	68
38	120	34	70.17 -37.60~97.00	33.36 -31.20~79.50	-96.51 -271.70~82.00	55.92 -7.70~88.30	164.27 90.00~264.20	6.19 -66.40~68.10	0.42 0.01~0.98	正走滑	69
39	120	35	-90.43 -269.20~89.40	25.99 -61.70~89.80	72.15 -106.00~251.80	62.94 -24.90~89.40	176.12 153.50~196.60	7.03 -16.30~44.90	0.69 0.16~0.99	正走滑	7
40	120	37	88.48 70.60~111.70	35.92 -7.20~74.60	-103.22 -268.70~34.90	53.50 14.20~86.90	-5.60 -36.20~46.00	5.60 -45.00~38.60	0.47 0.06~0.95	正走滑	5
41	121	31	88.96 -86.90~250.60	20.02 -67.40~86.90	-59.31 -236.40~114.70	66.81 -20.00~89.00	-176.90 -199.50~-154.00	11.22 -22.30~45.00	0.69 0.07~1.00	正走滑	10
42	121	32	94.34 -45.70~271.60	62.94 -24.00~88.20	-124.31 -303.40~55.30	21.75 -66.40~89.80	-28.04 -54.20~-0.60	15.30 -44.40~37.90	0.87 0.19~1.00	正断	34
43	121	33	-113.89 -131.50~-99.30	5.60 -80.10~49.20	71.61 -107.70~251.60	84.38 9.30~90.00	-23.84 -37.80~-9.00	0.54 -45.80~47.60	0.49 0.04~0.96	走滑	32
44	121	34	80.81 60.20~100.70	0.30 -29.80~31.10	-10.52 -190.40~169.40	77.22 -10.80~89.70	170.88 7.40~338.20	12.78 -76.00~87.20	0.25 0.01~0.87	走滑	27
45	121	35	87.74 -90.00~253.40	9.20 -79.00~87.20	-120.65 -300.30~59.30	79.57 -8.30~88.50	-3.05 -172.50~75.60	4.88 -83.20~89.40	0.45 0.01~0.98	走滑	11
46	121	36	89.94 -65.30~102.10	10.86 -75.20~81.90	-89.47 -268.80~90.20	79.14 -8.20~89.30	179.96 168.50~193.90	0.11 -18.00~45.00	0.64 0.31~0.98	走滑	5
47	121	37	88.25 71.60~224.10	24.87 -56.30~81.10	-112.38 -278.10~56.00	63.65 -9.70~89.40	-5.56 -21.00~11.80	8.15 -44.80~31.00	0.61 0.30~1.00	正走滑	5
48	122	32	-110.19 -283.50~53.00	19.46 -68.50~87.20	104.71 -75.20~284.40	66.69 -19.00~89.40	-15.76 -70.90~96.40	12.32 -73.40~74.70	0.51 0.02~0.95	走滑	15
49	122	33	63.12 44.60~88.30	7.40 -16.20~28.40	160.88 10.70~339.00	46.11 -41.50~88.20	-33.83 -205.40~126.80	42.94 -44.40~88.90	0.32 0~0.71	逆走滑	19
50	122	35	-101.78 -280.90~77.00	29.76 -58.40~86.80	46.15 -113.90~224.70	55.99 -29.60~87.90	159.45 135.00~182.20	14.94 -15.10~48.10	0.67 0.09~0.99	正走滑	7

序号	网格节点		σ₁轴		σ₂轴		σ₃轴		R值	应力类型	震源机制解数目
	东经/(°)	北纬/(°)	方位角/(°)	倾伏角/(°)	方位角/(°)	倾伏角/(°)	方位角/(°)	倾伏角/(°)
1	115	30	95.23 34.30~174.70	2.77 -77.40~84.90	-18.15 -197.60~160.30	83.05 1.20~89.20	-174.46 -206.10~-39.20	6.37 -68.90~81.60	0.52 0.02~0.99	走滑	19
2	115	31	-82.51 -149.00~64.90	7.29 -81.60~88.80	36.37 -143.60~215.50	75.16 -13.20~89.00	-174.18 -198.70~-153.20	12.86 -76.60~63.30	0.62 0.03~0.99	走滑	8
3	115	32	90.54 -67.70~225.10	15.56 -61.20~88.80	-58.93 -233.30~120.60	72.09 -12.90~89.40	-177.03 -223.40~-97.70	8.66 -53.30~72.40	0.47 0.01~0.98	走滑	30
4	115	33	92.92 72.10~111.00	16.30 -19.40~53.00	-132.70 -301.00~33.30	67.31 10.40~88.40	-1.68 -60.60~21.60	15.34 -44.90~71.50	0.49 0.05~0.97	走滑	9
5	115	34	-89.94 -262.60~71.20	5.64 -83.10~88.60	133.70 -45.70~312.90	82.23 -6.70~89.50	0.59 -30.50~40.30	5.32 -49.90~58.30	0.65 0.07~1.00	走滑	8
6	115	35	-107.47 -123.00~-93.30	4.68 -31.60~36.00	-1.49 -180.90~177.40	73.44 8.10~89.60	161.20 109.00~175.70	15.84 -35.50~77.70	0.46 0.04~0.98	走滑	11
7	115	36	102.20 71.50~129.40	17.74 -41.60~54.70	-21.80 -192.60~158.20	60.23 -23.00~89.20	-159.96 -198.50~-6.40	23.08 -59.20~84.50	0.37 0.02~0.90	走滑	45
8	116	30	-85.55 -106.00~0	7.05 -21.00~42.10	40.05 -137.00~215.50	78.01 -7.60~89.40	-176.76 -325.80~-78.40	9.65 -78.80~87.40	0.32 0.01~0.87	走滑	18
9	116	31	-85.42 -97.80~0	6.73 -19.30~35.70	121.26 -58.20~299.00	82.48 54.80~89.60	4.97 -7.50~13.70	3.35 -45.00~21.90	0.57 0.30~0.87	走滑	101
10	116	32	-86.05 -97.90~0	1.86 -23.90~23.90	175.83 -4.10~350.00	77.07 60.50~89.60	4.37 -9.80~9.60	12.79 -45.00~25.50	0.52 0.24~0.87	走滑	78
11	116	33	91.83 77.70~105.20	8.46 -6.90~26.30	-151.27 -275.10~4.10	71.81 47.00~88.50	-0.61 -15.00~15.60	15.99 -44.80~42.20	0.39 0.11~0.75	走滑	14
12	116	34	-93.70 -112.70~-52.20	8.35 -70.90~68.10	142.03 -23.20~322.00	75.38 15.50~89.70	-1.93 -16.50~11.40	11.91 -45.00~37.20	0.66 0.21~0.98	走滑	5
13	116	35	-101.24 -116.70~-86.30	14.13 -8.10~42.30	39.41 -75.90~217.90	71.96 -10.90~89.30	165.96 38.60~187.90	10.97 -55.60~81.30	0.41 0.02~0.87	走滑	6
14	116	36	95.01 -58.80~221.50	6.74 -82.70~89.20	-69.19 -249.00~110.80	83.00 -5.80~89.60	-174.77 -230.00~-109.30	1.89 -80.40~81.20	0.52 0.02~0.99	走滑	9
15	117	30	-87.49 -104.00~0	10.07 -14.60~28.90	39.63 -140.00~219.10	73.61 -11.00~89.50	-179.80 -338.00~-118.60	12.80 -67.60~88.00	0.28 0.01~0.70	走滑	6
16	117	31	88.27 73.50~100.20	10.43 -14.90~29.30	-155.06 -209.60~-9.90	67.70 -14.00~87.70	-5.46 -146.50~26.20	19.48 -57.20~78.50	0.31 0.02~0.69	走滑	44
17	117	32	93.42 77.80~180.00	2.02 -21.00~23.30	-170.40 -349.80~9.00	71.89 12.10~89.20	2.77 -25.50~15.50	17.99 -69.00~76.60	0.35 0.03~0.73	走滑	32
18	117	33	-90.96 -105.40~-77.80	2.75 -32.90~35.10	101.38 -78.60~281.30	87.18 53.90~90.00	-0.94 -17.60~12.50	0.60 -45.00~33.30	0.48 0.11~0.91	走滑	35
19	117	34	-101.27 -114.20~-91.10	17.07 -4.90~34.70	98.12 -1.80~200.90	71.96 48.60~86.90	-9.54 -24.20~3.50	5.64 -44.20~32.20	0.44 0.15~0.74	走滑	13
20	117	35	-100.46 -110.00~-88.40	17.28 -2.50~34.50	73.38 -39.00~191.70	72.63 5.00~89.80	168.99 99.70~224.80	1.75 -70.80~66.90	0.36 0~0.75	走滑	16
21	117	36	87.73 -91.50~267.70	46.88 -42.60~88.50	-91.16 -268.80~88.80	43.11 -45.80~89.10	178.33 147.10~211.10	0.55 -38.90~45.00	0.69 0.14~0.98	正走滑	13
22	118	31	78.68 35.80~118.30	2.29 -48.50~49.60	172.22 0.70~350.40	57.04 -31.60~88.00	-12.81 -190.70~126.10	32.86 -55.30~81.40	0.46 0.01~0.98	走滑	27
23	118	32	-104.15 -119.80~-93.40	3.47 -17.90~23.10	153.88 -25.60~333.80	73.69 -16.00~89.70	-13.16 -43.30~149.40	15.92 -71.50~86.30	0.30 0.01~0.73	走滑	28
24	118	33	-95.62 -107.50~-88.70	17.37 -2.60~41.80	97.86 10.50~195.30	72.17 47.60~88.50	-4.39 -22.10~4.30	3.90 -44.80~25.10	0.50 0.21~0.78	走滑	12
25	118	34	-102.39 -113.20~-92.10	22.50 8.40~30.30	118.81 19.90~156.60	61.17 43.70~78.20	-5.09 -33.70~6.40	17.07 -43.40~39.20	0.31 0.04~0.57	正走滑	19
26	118	35	-101.41 -111.00~-90.90	7.74 -9.30~19.90	57.53 -121.30~236.10	81.72 6.10~89.80	168.19 110.80~186.20	2.94 -66.00~78.80	0.34 0~0.67	走滑	20
27	118	36	75.77 -75.70~94.40	13.17 -43.00~77.10	-59.69 -228.80~118.00	71.82 -11.80~89.30	168.70 157.00~183.80	12.30 -10.40~45.00	0.62 0.22~0.96	走滑	22
28	118	37	85.56 -69.70~264.40	43.33 -44.20~89.50	-104.75 -284.70~74.20	46.21 -42.50~89.40	-9.34 -23.70~18.00	5.17 -45.00~20.40	0.71 0.29~0.98	正走滑	11
29	119	31	-97.55 -116.50~-74.40	1.77 -73.80~52.90	155.65 -24.00~335.40	83.89 14.90~89.90	-7.37 -22.30~7.20	5.85 -45.00~31.70	0.59 0.14~0.98	走滑	36
30	119	32	-95.42 -123.10~-81.50	4.79 -39.10~53.00	160.98 -12.10~340.30	70.39 30.70~89.20	-3.76 -23.70~12.00	18.97 -45.00~47.80	0.53 0.13~0.94	走滑	37
31	119	33	-109.72 -123.10~-47.70	3.12 -70.50~81.70	28.70 -149.70~208.40	85.84 3.40~89.80	160.13 151.70~169.30	2.76 -11.00~44.20	0.72 0.44~0.98	走滑	31
32	119	34	-109.02 -288.20~55.80	6.93 -82.70~87.80	59.28 -120.60~239.20	82.93 -6.70~89.60	160.81 148.60~172.50	1.42 -10.50~44.30	0.91 0.51~0.99	走滑	8
33	119	35	-99.31 -277.10~77.40	34.73 -53.00~87.20	68.72 -108.70~244.00	54.68 -31.70~89.00	166.75 148.50~186.60	5.66 -15.30~44.80	0.71 0.25~0.99	正走滑	27
34	119	36	76.52 -99.50~227.80	16.53 -72.20~82.20	-125.24 -303.40~50.60	72.28 -13.30~89.70	-15.33 -27.50~-0.20	6.21 -45.00~24.30	0.65 0.30~0.97	走滑	24
35	120	31	98.69 -80.70~277.70	15.69 -69.30~87.20	-59.29 -239.00~120.50	73.14 -15.00~89.40	-169.62 -306.80~-4.70	6.01 -69.50~84.20	0.41 0.02~0.98	走滑	18
36	120	32	86.26 6.40~242.40	15.00 -74.60~84.90	-102.95 -282.10~76.70	74.81 -14.50~89.50	-4.36 -99.10~77.90	2.32 -84.70~85.50	0.41 0~0.99	走滑	29
37	120	33	-109.84 -120.10~-101.40	12.35 -11.30~32.20	37.54 -139.70~216.70	75.43 57.00~89.50	158.48 148.50~168.10	7.61 -8.70~43.80	0.61 0.31~0.84	走滑	68
38	120	34	70.17 -37.60~97.00	33.36 -31.20~79.50	-96.51 -271.70~82.00	55.92 -7.70~88.30	164.27 90.00~264.20	6.19 -66.40~68.10	0.42 0.01~0.98	正走滑	69
39	120	35	-90.43 -269.20~89.40	25.99 -61.70~89.80	72.15 -106.00~251.80	62.94 -24.90~89.40	176.12 153.50~196.60	7.03 -16.30~44.90	0.69 0.16~0.99	正走滑	7
40	120	37	88.48 70.60~111.70	35.92 -7.20~74.60	-103.22 -268.70~34.90	53.50 14.20~86.90	-5.60 -36.20~46.00	5.60 -45.00~38.60	0.47 0.06~0.95	正走滑	5
41	121	31	88.96 -86.90~250.60	20.02 -67.40~86.90	-59.31 -236.40~114.70	66.81 -20.00~89.00	-176.90 -199.50~-154.00	11.22 -22.30~45.00	0.69 0.07~1.00	正走滑	10
42	121	32	94.34 -45.70~271.60	62.94 -24.00~88.20	-124.31 -303.40~55.30	21.75 -66.40~89.80	-28.04 -54.20~-0.60	15.30 -44.40~37.90	0.87 0.19~1.00	正断	34
43	121	33	-113.89 -131.50~-99.30	5.60 -80.10~49.20	71.61 -107.70~251.60	84.38 9.30~90.00	-23.84 -37.80~-9.00	0.54 -45.80~47.60	0.49 0.04~0.96	走滑	32
44	121	34	80.81 60.20~100.70	0.30 -29.80~31.10	-10.52 -190.40~169.40	77.22 -10.80~89.70	170.88 7.40~338.20	12.78 -76.00~87.20	0.25 0.01~0.87	走滑	27
45	121	35	87.74 -90.00~253.40	9.20 -79.00~87.20	-120.65 -300.30~59.30	79.57 -8.30~88.50	-3.05 -172.50~75.60	4.88 -83.20~89.40	0.45 0.01~0.98	走滑	11
46	121	36	89.94 -65.30~102.10	10.86 -75.20~81.90	-89.47 -268.80~90.20	79.14 -8.20~89.30	179.96 168.50~193.90	0.11 -18.00~45.00	0.64 0.31~0.98	走滑	5
47	121	37	88.25 71.60~224.10	24.87 -56.30~81.10	-112.38 -278.10~56.00	63.65 -9.70~89.40	-5.56 -21.00~11.80	8.15 -44.80~31.00	0.61 0.30~1.00	正走滑	5
48	122	32	-110.19 -283.50~53.00	19.46 -68.50~87.20	104.71 -75.20~284.40	66.69 -19.00~89.40	-15.76 -70.90~96.40	12.32 -73.40~74.70	0.51 0.02~0.95	走滑	15
49	122	33	63.12 44.60~88.30	7.40 -16.20~28.40	160.88 10.70~339.00	46.11 -41.50~88.20	-33.83 -205.40~126.80	42.94 -44.40~88.90	0.32 0~0.71	逆走滑	19
50	122	35	-101.78 -280.90~77.00	29.76 -58.40~86.80	46.15 -113.90~224.70	55.99 -29.60~87.90	159.45 135.00~182.20	14.94 -15.10~48.10	0.67 0.09~0.99	正走滑	7

郯庐断裂带鲁苏皖段及邻区构造应力场特征及其动力学意义

CHARACTERISTICS OF TECTONIC STRESS FIELD AND DYNAMIC SIGNIFICANCE IN THE SHANDONG-JIANGSU-ANHUI SEGMENT OF TANCHENG-LUJIANG FAULT ZONE AND ITS ADJACENT AREAS

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