THE LATEST DEFORMATION STYLE ALONG THE NORTH CHINA BLOCK REVEALED BY HIGH-RESOLUTION TOPOGRAPHIC DATA: A CASE STUDY ON XIADIAN FAULT

doi:10.3969/j.issn.0253-4967.2022.01.007

Abstract

Abstract:

Beijing locates in the North China active tectonic block, where the NW- and NE-trending active faults are widely distributed, such as the Nankou-Sunhe Fault, the Shunyi-Liangxiang Fault, and the Xiadian Fault. Historically, large earthquakes frequently occurred along these faults, especially in the intersection of these two sets of faults, e.g. the 1679 Sanhe-Pinggu earthquake(M~8). Thus, it is of great significance to quantitatively study the faults’ basic parameters, including the fault trace, slip distribution, and rupture behavior, for accurate assessment of seismic hazard of Beijing area.
The Xiadian active fault locates at the eastern boundary of Beijing, near the Beijing Municipal Administrative Center. The 1679 Sanhe-Pinggu earthquake(M~8)occurred on this fault. Previous studies on this area have revealed clearly the bedrock geology, fault geometry, seismicity distribution as well as co-seismic deformation of this earthquake, which greatly improves the understanding of the activity behavior of the Jiadian active fault.
However, the previous studies have focused on the surface rupture of the 1679 earthquake, the complete rupture geometry and slip distribution have not yet been constructed, due to the restriction of high-resolution topographic data. Furthermore, the triangular slip distribution has widely occurred along active faults, especially along the typical normal faults. Whether the fine slip distribution of Xiadian Fault conforms to the case or not is still unclear.
In order to explore all those issues above, using low-costing high-resolution(0.5m)satellite images, we derived 1.0m grid size DEM to quantitatively explore the surface rupture along the Xiadian Fault. Detailed mapping and offset measurements revealed 5 left-stepping branches(~3km), with a total length of 12.3km for the coseismic rupture of the 1679 Sanhe-Pinggu earthquake. Slip distributions along the fault exhibit the arc-shaped geometry, and the maximum and average vertical offsets are ~3.2m and ~1.8m, respectively.
Such triangular shaped slip distribution has also been found along other typical normal faults, for instance, the Wairarapa Fault in New Zealand, the Afar Fault in East Africa, and Owens Valley Fault in California. Modeling of these measurements revealed 2 earthquakes with co-seismic vertical offset of ~1.8m and 1.7m, respectively. Reasonably, the maximum ~3.2m vertical offset possibly represents the cumulative vertical offset of 2 earthquakes, including the 1679 Sanhe-Pinggu earthquake.
Based on the relationships among the surface rupture length, average offsets, as well as moment magnitudes, the calculated size is comparatively small. Based on the cutting shape of the 2 sets of faults and the upper crust imaging by shallow seismic reflection profile, we propose that the current right-lateral shear deformation of the fault is decoupled with the existing extensional structures, and this hypothesis has been verified by the current focal mechanism solution.

Key words: Xiadian Fault, high-resolution topographic data, vertical offsets, surface rupture

摘要：

文中利用高分辨率“吉林一号”卫星影像数据, 获得了夏垫断裂沿线高精度DEM数据(1.0m)。基于高精度地形数据对夏垫断裂开展了定量研究, 揭示出1679年三河-平谷地震地表破裂由5条大致呈左阶平行展布的、长约3km的分支断层组成, 地表破裂的总长度约为12.3km。位错测量揭示出断裂垂直位移沿断层呈不对称三角形分布, 存在2个明显波峰。断裂沿线的平均位移值为1.8m, 约3.2m的最大位移值分布在潘各庄附近。位错模拟分析表明, 其可能代表了2次地震事件的累积位错。根据夏垫断裂上代表华北地区最新构造变形的地表破裂带相关定量参数估算的震级(约 M_W6.3 或 M_S6.25 ), 与1679年三河-平谷地震的历史震级(约M8.0或 M_S8.0 )存在较大差异。这可能与华北地区现今剪切走滑构造变形与早期分布于上地壳的断陷拉张构造在孕震层存在的解耦作用, 或华北地区巨厚的第四纪覆盖层对构造变形的吸收作用相关, 这种假设也被浅层地震反射剖面揭示的断层切割关系和现今走滑型的震源机制所印证。

关键词: 夏垫断裂, 高精度地形数据, 垂直位错, 地表破裂

CLC Number:

P315.2

LI Zhan-fei, XU Xi-wei, MENG Yong-qi, ZHAO Shuai, SUN Jia-jun, CHENG Jia, LI Kang, KANG Wen-jun. THE LATEST DEFORMATION STYLE ALONG THE NORTH CHINA BLOCK REVEALED BY HIGH-RESOLUTION TOPOGRAPHIC DATA: A CASE STUDY ON XIADIAN FAULT[J]. SEISMOLOGY AND GEOLOGY, 2022, 44(1): 98-114.

李占飞, 徐锡伟, 孟勇琦, 赵帅, 孙佳珺, 程佳, 李康, 康文君. 基于“吉林一号”高精度遥感数据研究华北地区最新构造变形样式——以夏垫断裂1679年三河-平谷地震地表破裂为例[J]. 地震地质, 2022, 44(1): 98-114.

Figures/Tables 9

References 45

[1]	北京市地质矿产局. 1991. 北京市区域地质志[M]. 北京: 地质出版社.
	Bureau of Geology and Mineral Resources of Beijing Municipality. 1991. Regional Geology of Beijing Municipality[M]. Geological Publishing House, Beijing. (in Chinese)
[2]	陈成沟, 邢成起, 胡乐银, 等. 2017. 北京及其邻区小震重定位与活动构造分析[J]. 地震, 37(3): 84-94.
	CHEN Cheng-gou, XING Cheng-qi, HU Le-yin, et al. 2017. Relocation of small earthquakes and active tectonics in Beijing and its adjacent areas[J]. Earthquake, 37(3): 84-94. (in Chinese)
[3]	高文学, 马瑾. 1993. 首都圈地震地质环境与地震灾害[M]. 北京: 地震出版社: 3-51.
	GAO Wen-xue, MA Jin. 1993. Seismo-geological Background and Earthquake Hazard in Beijing Area[M]. Seismological Press, Beijing: 3-51. (in Chinese)
[4]	高战武, 陈棋福, 黄金莉, 等. 2010. 北京地区主要活动断裂深部速度结构特征及强震构造分析[J]. 震灾防御技术, 5(3): 271-280.
	GAO Zhan-wu, CHEN Qi-fu, HUANG Jin-li, et al. 2010. Velocity structure beneath the active faults in Beijing area and their seismotectonic characteristics[J]. Technology for Earthquake Disaster Prevention, 5(3): 271-280. (in Chinese)
[5]	高战武, 徐杰, 宋长青, 等. 2001. 张家口-蓬莱断裂带的分段特征[J]. 华北地震科学, 19(1): 35-42.
	GAO Zhan-wu, XU Jie, SONG Chang-qing, et al. 2001. The segmental character of Zhangjiakou-Penglai Fault[J]. North China Earthquake Science, 19(1): 35-42. (in Chinese)
[6]	江娃利, 侯治华, 肖振敏, 等. 2000. 北京平原夏垫断裂齐心庄探槽古地震事件分析[J]. 地震地质, 22(4): 413-422.
	JIANG Wa-li, HOU Zhi-hua, XIAO Zhen-min, et al. 2000. Study on paleoearthquakes of Qixinzhuang trench at the Xiadian Fault, Beijing plain[J]. Seismology and Geology, 22(4): 413-422. (in Chinese)
[7]	李乐, 陈棋福, 陈颙. 2007. 首都圈地震活动构造成因的小震精定位分析[J]. 地球物理学进展, 22(1): 24-34.
	LI Le, CHEN Qi-fu, CHEN Yong. 2007. Relocated seismicity in Big Beijing area and its tectonic implication[J]. Progress in Geophysics, 22(1): 24-34. (in Chinese)
[8]	林向东, 袁怀玉, 徐平, 等. 2017. 华北地区地震震源机制分区特征[J]. 地球物理学报, 60(12): 4589-4622.
	LIN Xiang-dong, YUAN Huai-yu, XU Ping, et al. 2017. Zonational characteristics of earthquake focal mechanism solutions in North China[J]. Chinese Journal of Geophysics, 60(12): 4589-4622. (in Chinese)
[9]	刘保金, 寇昆朋, 胡平, 等. 2009. 北京平原西北部地壳浅部结构和隐伏活动断裂: 由地震反射剖面揭示[J]. 地球物理学报, 52(8): 2015-2025.
	LIU Bao-jin, KOU Kun-peng, HU Ping, et al. 2009. The crustal shallow structures and buried active faults revealed by seismic reflection profiles in northwestern area of Beijing plain[J]. Chinese Journal of Geophysics, 52(8): 2015-2025. (in Chinese)
[10]	刘保金, 张先康, 陈颙, 等. 2011. 三河-平谷8.0级地震区地壳结构和活动断裂研究: 利用单次覆盖深反射和浅层地震剖面[J]. 地球物理学报, 54(5): 1251-1259.
	LIU Bao-jin, ZHANG Xian-kang, CHEN Yong, et al. 2011. Research on crustal structure and active fault in the Sanhe-Pinggu earthquake(M8.0)zone based on single-fold deep seismic reflection and shallow seismic reflection profiling[J]. Chinese Journal of Geophysics, 54(5): 1251-1259. (in Chinese)
[11]	刘瑞丰, 陈运泰, 任枭, 等. 2015. 震级的测定[M]. 北京: 地震出版社: 3-28.
	LIU Rui-feng, CHEN Yun-tai, REN Xiao, et al. 2015. Determination of Earthquake Magnitude[M]. Seismological Press, Beijing: 3-28. (in Chinese)
[12]	刘瑞丰, 陈运泰, 王丽艳. 2018. 新的震级国家标准的技术要点与主要特点[J]. 地震地磁观测与研究, 39(1): 1-11.
	LIU Rui-feng, CHEN Yun-tai, WANG Li-yan. 2018. The technical key points and main features of the new national standard of magnitude[J]. Seismological and Geomagnetic Observation and Research, 39(1): 1-11. (in Chinese)
[13]	毛昌伟, 丁锐, 龚正, 等. 2010. 1679年三河-平谷8级地震地表断层陡坎的GPS测量 [G]. 中国地震局地壳应力研究所. 地壳构造与地壳应力文集: 17-24.
	MAO Chang-wei, DING Rui, GONG Zheng, et al. 2010. GPS survey of the surface fault scarp of 1679 Sanhe-Pinggu M8 earthquake [G]. Bulletin of the Institute of Crustal Dynamics, 17-24. (in Chinese)
[14]	孟宪梁, 杜春涛, 王瑞, 等. 1983. 1679年三河-平谷大震的地震断裂带[J]. 地震, 3(3): 20-25.
	MENG Xian-liang, DU Chun-tao, WANG Rui, et al. 1983. Rupture of the Sanhe-Pinggu earthquake of 1679[J]. Earthquake, 3(3): 20-25. (in Chinese)
[15]	彭一民, 李鼎容, 谢振钊, 等. 1981. 北京平原区同生断裂的某些特征及其研究意义[J]. 地震地质, 3(2): 57-64.
	PENG Yi-min, LI Ding-rong, XIE Zhen-zhao, et al. 1981. Some features of contemporaneous faults in Beijing plain and their significance[J]. Seismology and Geology, 3(2): 57-64. (in Chinese)
[16]	冉勇康, 邓起东, 杨晓平, 等. 1997. 1679年三河-平谷8级地震发震断层的古地震及其重复间隔[J]. 地震地质, 19(3): 193-201.
	RAN Yong-kang, DENG Qi-dong, YANG Xiao-ping, et al. 1997. Paleoearthquakes and recurrence interval on the seismogenic fault of 1679 Sanhe-Pinggu M8 earthquake, Hebei and Beijing[J]. Seismology and Geology, 19(3): 193-201. (in Chinese)
[17]	向宏发, 方仲景, 徐杰, 等. 1988. 三河-平谷8级地震区的构造背景与大震重复性研究[J]. 地震地质, 10(1): 15-28.
	XIANG Hong-fa, FANG Zhong-jing, XU Jie, et al. 1988. Tectonic setting and earthquake repeatability on the seismogenic fault of 1679 M8.0 Sanhe-Pinggu earthquake[J]. Seismology and Geology, 10(1): 15-28. (in Chinese)
[18]	徐锡伟, 吴卫民, 张先康, 等. 2002. 首都圈地区地壳最新构造变动与地震[M]. 北京: 科学出版社: 3-28.
	XU Xi-wei, WU Wei-min, ZHANG Xian-kang, et al. 2002. The Latest Crustal Tectonic and Earthquakes in Capital Circle Area[M]. Science Press, Beijing: 3-28. (in Chinese)
[19]	于湘伟, 陈运泰, 张怀. 2010. 京津唐地区地壳三维P波速度结构与地震活动性分析[J]. 地球物理学报, 53(8): 1817-1828.
	YU Xiang-wei, CHEN Yun-tai, ZHANG Huai. 2010. Three-dimensional crustal P-wave velocity structure and seismicity analysis in Beijing-Tianjin-Tangshan region[J]. Chinese Journal of Geophysics, 53(8): 1817-1828. (in Chinese)
[20]	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 earthquakes in the continent of China[J]. Science in China(Ser D), 33(S1): 12-20. (in Chinese)
[21]	张培震, 邓起东, 张竹琪, 等. 2013. 中国大陆的活动断裂、地震灾害及其动力过程[J]. 中国科学(D辑), 43(10): 1607-1620.
	ZHANG Pei-zhen, DENG Qi-dong, ZHANG Zhu-qi, et al. 2013. Active faults, earthquake hazards and associated geodynamic processes in continental China[J]. Science in China(Ser D), 43(10): 1607-1620. (in Chinese)
[22]	张先康, 赵金仁, 刘国华, 等. 2002. 三河-平谷8.0级大震区震源细结构的深地震反射探测研究[J]. 中国地震, 18(4): 326-336.
	ZHANG Xian-kang, ZHAO Jin-ren, LIU Guo-hua, et al. 2002. Study on fine crustal structure of the Sanhe-Pinggu earthquake(M8.0)region by deep seismic reflection profiling[J]. Earthquake Research in China, 18(4): 326-336. (in Chinese)
[23]	赵成彬, 酆少英, 秦学业, 等. 2010. 夏垫断裂浅部特征高分辨反射地震探测研究[J]. 地震研究, 33(1): 81-85.
	ZHAO Cheng-bin, FENG Shao-ying, QIN Xue-ye, et al. 2010. Research on the shallow structure characteristics of Xiadian Fault using high-resolution artificial seismic exploration method[J]. Journal of Seismological Research, 33(1): 81-85. (in Chinese)
[24]	Bai L X, Xu X W, Luo H, et al. 2021. Angular unconformity of the late Quaternary strata in the Hetao Basin, north of the Ordos Block(West China): Timing and its tectonic implications[J]. Frontiers in Earth Science, 9(64789): 1-16.
[25]	Bi H Y, Zheng W, Ge W, et al. 2018. Constraining the distribution of vertical slip on the South Heli Shan Fault(northeastern Tibet)from high-resolution topographic data[J]. Journal of Geophysical Research: Solid Earth, 123(3): 2484-2501. DOI URL
[26]	Chen T, Liu-Zeng J, Shao Y, et al. 2018. Geomorphic offsets along the creeping Laohu Shan section of the Haiyuan Fault, northern Tibetan plateau[J]. Geosphere, 14(3): 1165-1186. DOI URL
[27]	Duross C B, Bunds M P, Gold R D, et al. 2019. Variable normal-fault rupture behavior, northern Lost River fault zone, Idaho, USA[J]. Geosphere, 15(6): 1869-1892. DOI URL
[28]	Haddon E K, Amos C B, Zielke O, et al. 2016. Surface slip during large Owens Valley earthquakes[J]. Geochemistry, Geophysics, Geosystems, 17(6): 2239-2269. DOI URL
[29]	Hanks T C, Kanamori H. 1979. A moment magnitude scale[J]. Journal of Geophysical Research: Solid Earth, 84(B5): 2348-2350.
[30]	Hetzel R, Hampel A, Gebbeken P, et al. 2019. A constant slip rate for the western Qilian Shan frontal thrust during the last 200ka consistent with GPS-derived and geological shortening rates[J]. Earth and Planetary Science Letters, 59:100-113.
[31]	Jiang W, Zhang J, Han Z, et al. 2017. Characteristic slip of strong earthquakes along the Yishu fault zone in East China evidenced by offset landforms[J]. Tectonics, 36(9-10): 1947-1965. DOI URL
[32]	Kang W, Xu X, Oskin M E, et al. 2019. Characteristic slip distribution and earthquake recurrence along the eastern Altyn Tagh Fault revealed by high-resolution topographic data[J]. Geosphere, 16(1): 392-406. DOI URL
[33]	Klinger Y, Etchebes M, Tapponnier P, et al. 2011. Characteristic slip for five great earthquakes along the Fuyun Fault in China[J]. Nature Geoscience, 4(6): 389-392. DOI URL
[34]	Liu M, Stein S, Wang H. 2011. 2000 years of migrating earthquakes in North China: How earthquakes in midcontinent differ from those at plate boundaries[J]. Lithosphere, 3(2): 128-132. DOI URL
[35]	Liu-Zeng J, Zhang Z, Wen L, et al. 2009. Co-seismic ruptures of the 12 May 2008, M_S8.0 Wenchuan earthquake, Sichuan: East-west crustal shortening on oblique, parallel thrusts along the eastern edge of Tibet[J]. Earth and Planetary Science Letters, 286(3-4): 355-370. DOI URL
[36]	Manighetti I, Caulet C, Barros L D, et al. 2015. Generic along-strike segmentation of Afar normal faults, East Africa: Implications on fault growth and stress heterogeneity on seismogenic fault planes[J]. Geochemistry Geophysics Geosystems, 16(2): 443-467. DOI URL
[37]	Manighetti I, Perrin C, Gaudemer Y, et al. 2020. Repeated giant earthquakes on the Wairarapa Fault, New Zealand, revealed by Lidar-based paleoseismology[J]. Scientific Reports, 10(1): 1-11. DOI URL
[38]	McGill S F, Sieh K. 1991. Surficial offsets on the central and eastern Garlock Fault associated with prehistoric earthquakes[J]. Journal of Geophysical Research: Solid Earth, 96(B13): 21597-21621.
[39]	Ren Z, Zhang Z, Chen T, et al. 2016. Clustering of offsets on the Haiyuan Fault and their relationship to paleo-earthquakes[J]. Geological Society of America Bulletin, 128(1-2): 3-18.
[40]	Shen Z K, Zhao C K, Yin A, et al. 2000. Contemporary crustal deformation in East Asia constrained by Global Positioning System measurements[J]. Journal of Geophysical Research, 105(B3): 5721-5734. DOI URL
[41]	Shi W, Dong S W, Hu J M. 2020. Neotectonics around the Ordos Block, North China: A review and new insights[J]. Earth-Science Reviews, 200(1): 102969. DOI URL
[42]	Sieh K, Jones L, Hauksson E, et al. 1993. Near-field investigations of the Landers earthquake sequence, April to July 1992 [J]. Science, 260(5105): 171-176. PMID
[43]	Wei Z Y, He H L, Sun W, et al. 2020. Investigating thrust-fault growth and segment linkage using displacement distribution analysis in the active Duzhanzi thrust fault zone, northern Tian Shan of China[J]. Journal of Structural Geology, 133: 103990. DOI URL
[44]	Wells D L, Coppersmith K J. 1994. New empirical relationships among magnitude, rupture length, rupture width, rupture area, and surface displacement[J]. Bulletin of the Seismological Society of America, 84(4): 974-1002.
[45]	Zielke O, Arrowsmith J R, Ludwig L G, et al. 2010. Slip in the 1857 and earlier large earthquakes along the Carrizo Plain, San Andreas Fault[J]. Science, 327(5969): 1119-1122. DOI PMID

编号	纬度	经度	位移值/m	误差/m	距离/m	确信度
0	39°56'7.865″N	116°53'11.381″E	0.71	0.12	0.00	2
1	39°56'17.207″N	116°53'16.538″E	1.25	0.21	312.06	2
2	39°56'25.711″N	116°53'23.051″E	1.28	0.13	617.31	2
4	39°56'38.515″N	116°53'39.880″E	1.45	0.12	1183.30	1
5	39°56'41.436″N	116°53'49.519″E	1.75	0.23	1431.16	4
6	39°56'46.029″N	116°53'57.489″E	1.78	0.11	1666.28	3
7	39°56'52.957″N	116°54'1.995″E	1.94	0.15	1905.16	4
^*8-1	39°56'57.440″N	116°54'12.577″E	1.20	0.13	2190.14	2
8	39°56'57.440″N	116°54'12.577″E	2.25	0.37	2190.14	2
9	39°57'3.791″N	116°54'19.172″E	2.45	0.13	2440.44	2
10	39°57'10.881″N	116°54'25.114″E	2.21	0.23	2701.44	2
^*11-1	39°57'17.456″N	116°54'30.418″E	1.20	0.10	2939.88	3
11	39°57'17.456″N	116°54'30.418E	2.08	0.18	2939.88	3
12	39°57'23.190″N	116°54'38.980″E	2.17	0.12	3208.88	3
13	39°57'30.981″N	116°54'44.087″E	1.90	0.17	3479.29	3
14	39°57'38.760″N	116°54' 49.957″E	1.62	0.12	3769.88	3
15	39°57'45.249″N	116°54'55.848″E	2.24	0.19	4015.88	3
16	39°57'51.248″N	116°55'3.132″E	1.98	0.10	4275.88	4
17	39°57'58.290″N	116°55'9.927″E	1.47	0.19	4545.88	4
18	39°58'4.988″N	116°55'16.946″E	2.00	0.15	4811.88	3
19	39°58'9.371″N	116°55'26.199″E	2.05	0.12	5071.88	4
^*20-1	39°58'14.525″N	116°55'32.997″E	1.30	0.20	5297.88	4
20	39°58'14.525″N	116°55'32.997″E	2.42	0.22	5297.88	4
21	39°58'19.746″N	116°55'40.657″E	2.89	0.20	5542.88	5
22	39°58'25.375″N	116°55'49.789″E	3.20	0.30	5822.88	5
^*23-1	39°58'32.529″N	116°55'57.400″E	1.56	0.20	6105.88	5
23	39°58'32.529″N	116°55'57.400″E	2.67	0.20	6105.88	5
24	39°58'39.348″N	116°56'8.108″E	2.24	0.19	6439.88	2
^*25-1	39°58'39.348″N	116°56'8.108″E	1.07	0.20	6929.88	2
25	39°58'47.433″N	116°56'26.066″E	1.92	0.13	6929.88	2
26	39°58'54.415″N	116°56'33.329″E	1.80	0.18	7206.88	3
28	39°59'7.057″N	116°56'48.822″E	1.72	0.28	7744.88	2
29	39°59'13.481″N	116°56'58.094″E	1.64	0.13	8039.88	2
31	39°59'27.196″N	116°57'24.771″E	1.65	0.19	8804.88	3
32	39°59'35.520″N	116°57'32.329″E	1.44	0.12	9122.88	3
33	39°59'43.783″N	116°57'40.395″E	1.60	0.18	9440.88	3
34	39°59'52.152″N	116°57'49.536″E	1.40	0.14	9773.88	3
35	39°59'59.124″N	116°57'57.855″E	1.75	0.33	10066.88	2
36	40°0'5.833″N	116°58'7.526″E	1.37	0.17	10372.88	2
37	40°0'13.136″N	116°58'17.105″E	1.14	0.19	10691.88	4
38	40°0'20.450″N	116°58'27.188″E	0.97	0.13	11018.88	3
39	40°0'27.675″N	116°58'36.895″E	1.02	0.12	11338.88	3
40	40°0'34.669″N	116°58'46.996″E	1.27	0.1	11664.88	2
41	40°0'41.872″N	116°58'57.548″E	1.25	0.19	12007.88	2

编号	纬度	经度	位移值/m	误差/m	距离/m	确信度
0	39°56'7.865″N	116°53'11.381″E	0.71	0.12	0.00	2
1	39°56'17.207″N	116°53'16.538″E	1.25	0.21	312.06	2
2	39°56'25.711″N	116°53'23.051″E	1.28	0.13	617.31	2
4	39°56'38.515″N	116°53'39.880″E	1.45	0.12	1183.30	1
5	39°56'41.436″N	116°53'49.519″E	1.75	0.23	1431.16	4
6	39°56'46.029″N	116°53'57.489″E	1.78	0.11	1666.28	3
7	39°56'52.957″N	116°54'1.995″E	1.94	0.15	1905.16	4
^*8-1	39°56'57.440″N	116°54'12.577″E	1.20	0.13	2190.14	2
8	39°56'57.440″N	116°54'12.577″E	2.25	0.37	2190.14	2
9	39°57'3.791″N	116°54'19.172″E	2.45	0.13	2440.44	2
10	39°57'10.881″N	116°54'25.114″E	2.21	0.23	2701.44	2
^*11-1	39°57'17.456″N	116°54'30.418″E	1.20	0.10	2939.88	3
11	39°57'17.456″N	116°54'30.418E	2.08	0.18	2939.88	3
12	39°57'23.190″N	116°54'38.980″E	2.17	0.12	3208.88	3
13	39°57'30.981″N	116°54'44.087″E	1.90	0.17	3479.29	3
14	39°57'38.760″N	116°54' 49.957″E	1.62	0.12	3769.88	3
15	39°57'45.249″N	116°54'55.848″E	2.24	0.19	4015.88	3
16	39°57'51.248″N	116°55'3.132″E	1.98	0.10	4275.88	4
17	39°57'58.290″N	116°55'9.927″E	1.47	0.19	4545.88	4
18	39°58'4.988″N	116°55'16.946″E	2.00	0.15	4811.88	3
19	39°58'9.371″N	116°55'26.199″E	2.05	0.12	5071.88	4
^*20-1	39°58'14.525″N	116°55'32.997″E	1.30	0.20	5297.88	4
20	39°58'14.525″N	116°55'32.997″E	2.42	0.22	5297.88	4
21	39°58'19.746″N	116°55'40.657″E	2.89	0.20	5542.88	5
22	39°58'25.375″N	116°55'49.789″E	3.20	0.30	5822.88	5
^*23-1	39°58'32.529″N	116°55'57.400″E	1.56	0.20	6105.88	5
23	39°58'32.529″N	116°55'57.400″E	2.67	0.20	6105.88	5
24	39°58'39.348″N	116°56'8.108″E	2.24	0.19	6439.88	2
^*25-1	39°58'39.348″N	116°56'8.108″E	1.07	0.20	6929.88	2
25	39°58'47.433″N	116°56'26.066″E	1.92	0.13	6929.88	2
26	39°58'54.415″N	116°56'33.329″E	1.80	0.18	7206.88	3
28	39°59'7.057″N	116°56'48.822″E	1.72	0.28	7744.88	2
29	39°59'13.481″N	116°56'58.094″E	1.64	0.13	8039.88	2
31	39°59'27.196″N	116°57'24.771″E	1.65	0.19	8804.88	3
32	39°59'35.520″N	116°57'32.329″E	1.44	0.12	9122.88	3
33	39°59'43.783″N	116°57'40.395″E	1.60	0.18	9440.88	3
34	39°59'52.152″N	116°57'49.536″E	1.40	0.14	9773.88	3
35	39°59'59.124″N	116°57'57.855″E	1.75	0.33	10066.88	2
36	40°0'5.833″N	116°58'7.526″E	1.37	0.17	10372.88	2
37	40°0'13.136″N	116°58'17.105″E	1.14	0.19	10691.88	4
38	40°0'20.450″N	116°58'27.188″E	0.97	0.13	11018.88	3
39	40°0'27.675″N	116°58'36.895″E	1.02	0.12	11338.88	3
40	40°0'34.669″N	116°58'46.996″E	1.27	0.1	11664.88	2
41	40°0'41.872″N	116°58'57.548″E	1.25	0.19	12007.88	2

计算方法	断层类型	计算公式	计算结果/M_W
地表破裂长度(SRL)	正断层	M=4.86+1.32×lg(SRL)	6.29
	通用	M=5.08+1.16×lg(SRL)	6.34
破裂面积(RA)	正断层	M=3.93+1.02×lg(RA)	6.24
	通用	M=4.07+0.98×lg(RA)	6.29
平均位移(AD)	正断层	M=6.78+0.65×lg(AD)	6.95
	通用	M=6.93+0.82×lg(AD)	7.15

计算方法	断层类型	计算公式	计算结果/M_W
地表破裂长度(SRL)	正断层	M=4.86+1.32×lg(SRL)	6.29
	通用	M=5.08+1.16×lg(SRL)	6.34
破裂面积(RA)	正断层	M=3.93+1.02×lg(RA)	6.24
	通用	M=4.07+0.98×lg(RA)	6.29
平均位移(AD)	正断层	M=6.78+0.65×lg(AD)	6.95
	通用	M=6.93+0.82×lg(AD)	7.15