SIMULATION OF POST-SEISMIC EFFECTS OF THE MADUO MS7.4 EARTHQUAKE IN 2021

doi:10.3969/j.issn.0253-4967.2021.04.013

Abstract

Abstract:

Using the fault model issued by the USGS, and based on the dislocation theory and local crust-upper-mantle model layered by average wave velocity, the co-seismic and post-seismic deformation and gravity change caused by the 2021 Maduo M_S7.4 earthquake in an elastic-viscoelastic layered half space are simulated. The simulation results indicate that: the co-seismic deformation and gravity change show that the earthquake fault is characterized by left-lateral strike-slip with normal faulting. The changes are concentrated mainly in 50km around the projection area of the fault on the surface and rapidly attenuate to both sides of the fault, with the largest deformation over 1 000mm on horizontal displacement, 750mm on the vertical displacement, and 150μGal on gravity change. The horizontal displacement in the far field(beyond 150km from the fault)is generally less than 10mm, and attenuates outward slowly. The vertical displacement and gravity change patterns show a certain negative correlation with a butterfly-shaped positive and negative symmetrical four-quadrant distribution. Their attenuation rate is obviously larger than the horizontal displacement, and the value is generally less than 2mm and 1 micro-gal. The post-seismic effects emerge gradually and increase continuously with time, similar to the coseismic effects and showing an increasing trend of inheritance obviously. The post-seismic viscoelastic relaxation effects can influence a much larger area than the co-seismic effect, and the effects during the 400 years after the earthquake in the near-field area will be less than twice of the co-seismic effects, but in the far-field it is more than 3 times. The viscoelastic relaxation effects on the horizontal displacement, vertical displacement and gravity change can reach to 100mm, 130mm and 30 micro-gal, respectively. The co-seismic extremum is mainly concentrated on both sides of the fault, while the post-earthquake viscoelastic relaxation effects are 50km from the fault, the two effects do not coincide with each other. The post-seismic horizontal displacement keeps increasing or decreasing with time, while the vertical displacement and gravity changes are relatively complex, which show an inherited increase relative to the co-seismic effects in the near-field within 5 years after the earthquake, then followed by reverse-trend adjustment, while in the far-field, they are just the opposite, with reverse-trend adjustment first, and then the inherited increase. The horizontal displacement will almost be stable after 100 years, while the viscoelastic effects on the vertical displacement and gravity changes will continue to 300 years after the earthquake. Compared with the GNSS observation results, we can find that the observed and simulated results are basically consistent in vector direction and magnitude, and the consistency is better in the far-field, which may be related to the low resolution of the fault model. The simulation results in this paper can provide a theoretical basis for explaining the seismogenic process of this earthquake using GNSS and gravity data.

Key words: Maduo earthquake, gravity change, displacement, viscoelastic relaxation, dislocation

摘要：

文中基于矩形位错理论及USGS发布的断层模型, 结合研究区地壳-上地幔平均波速分层结构, 模拟计算了弹性-黏弹分层半空间中2021年玛多M_S7.4地震产生的同震及震后地表形变和重力变化。经分析发现, 同震形变和重力变化显示发震断层具有左旋走滑兼正断错动的综合特征, 其变化主要发生于断层在地表投影周边50km的范围内, 向断层两侧快速衰减, 向E最大水平位移量>1 000mm, 向N最大位移量达570mm, 垂直位移近750mm, 重力变化达150μGal; 远震区(与断层的距离>150km)的水平位移量值一般<10mm, 向外衰减较慢; 而垂直位移和重力变化图像呈现一定的负相关, 呈蝴蝶状的正负四象限对称分布, 向外衰减的速率明显强于水平形变, 变化量值一般<2mm和<1μGal。震后效应随时间的推移逐步显现并持续增强, 其图像变化形态与同震类似, 表现出明显的继承性增强趋势; 震后黏弹性松弛效应的影响范围远大于同震, 震后400a间其影响量值在近场区一般≤同震的2倍, 但远场区均>3倍; 震后400a间黏弹性松弛对水平位移、垂直位移和重力变化的影响可达100mm、 130mm和30μGal; 同震效应的极值区域主要集中在断层两侧, 且离断层越近量值越大, 而震后黏弹性松弛效应的极值区分布于离断层两侧约50km处, 两者并不重合; 震后水平位移主要表现为持续单调增强, 而垂直位移和重力震后的变化则相对复杂: 近场区在震后5a内呈现相对同震的继承性增强, 随后反向调整, 而远场区则相反, 先反向调整, 后呈继承性增强; 水平位移在100a后基本稳定不变, 而黏弹性松弛效应对垂直位移和重力变化的影响会持续到震后300a。与GNSS实测结果对比后发现, 两者在运动方向和量级大小上基本一致, 远场符合更好, 这可能与断层模型的分辨率有关。文中研究可为利用实际形变和重力资料解释此次地震的孕震过程研究提供理论依据。

关键词: 玛多地震, 重力变化, 形变, 黏弹性松弛, 位错

CLC Number:

P315.72

TAN Hong-bo, WANG Jia-pei, YANG Guang-liang, CHEN Zheng-song, WU Gui-ju, SHEN Chong-yang, HUANG Jin-shui. SIMULATION OF POST-SEISMIC EFFECTS OF THE MADUO M_S7.4 EARTHQUAKE IN 2021[J]. SEISMOLOGY AND EGOLOGY, 2021, 43(4): 936-957.

谈洪波, 王嘉沛, 杨光亮, 陈正松, 吴桂桔, 申重阳, 黄金水. 2021年玛多M_S7.4地震的震后效应模拟[J]. 地震地质, 2021, 43(4): 936-957.

Figures/Tables 12

Fig. 1 Distribution of the main structures in the study area.

Fig. 2 Dislocation model of a rectangle fault.

Fig. 3 The SLS rheological model.

Table1 The layered structure of the crust-upper-mantle based on Crust 1.0

分层	h/km	V_P/km·s^-1	V_S/km·s^-1	ρ/kg·m^-3	η/Pa·s
上地壳	0.0~28.0	6.03	3.53	2.726×10³	∞
中地壳	28.0~44.4	6.30	3.67	2.788×10³	∞
下地壳	44.4~58.2	6.72	3.873	2.881×10³	1.5×10¹⁸
上地幔	58.2~ $∞$	8.17	4.53	3.364×10³	1.5×10¹⁹

Table1 The layered structure of the crust-upper-mantle based on Crust 1.0

分层	h/km	V_P/km·s^-1	V_S/km·s^-1	ρ/kg·m^-3	η/Pa·s
上地壳	0.0~28.0	6.03	3.53	2.726×10³	∞
中地壳	28.0~44.4	6.30	3.67	2.788×10³	∞
下地壳	44.4~58.2	6.72	3.873	2.881×10³	1.5×10¹⁸
上地幔	58.2~ $∞$	8.17	4.53	3.364×10³	1.5×10¹⁹

Fig. 4 The slip distribution on the fault plane(according to USGS results).

Fig. 5 Surface co-seismic effects.

Fig. 6 Simulation of the surface viscoelastic relaxation effects after the earthquake.

Table2 The post-seismic effects on some of the cities

点位	德令哈(37.369°N, 97.356°E)				囊谦(32.208°N, 96.477°E)				阿坝(32.899°N, 101.706°E)
	位移/mm			重力变化 /μGal	位移/mm			重力变化 /μGal	位移/mm			重力变化 /μGal
	经度方向	纬度方向	垂向		经度方向	纬度方向	垂向		经度方向	纬度方向	垂向
同震	-1.8	3.2	-0.9	0.32	2.0	1.3	1.0	-0.32	2.0	-2.1	-0.8	0.26
1a	-2.0	3.8	-0.9	0.31	2.2	1.6	1.0	-0.32	2.4	-2.4	-0.7	0.25
2a	-2.2	4.6	-0.8	0.30	2.5	2.1	1.0	-0.32	3.0	-2.7	-0.7	0.25
3a	-2.4	5.3	-0.8	0.30	2.9	2.6	0.9	-0.32	3.5	-3.0	-0.7	0.25
5a	-2.9	6.8	-0.7	0.28	3.5	3.4	0.9	-0.32	4.5	-3.7	-0.6	0.24
10a	-4.0	10.0	-0.5	0.26	5.1	5.2	0.8	-0.31	6.8	-5.2	-0.4	0.22
20a	-6.2	14.8	-0.3	0.23	8.0	7.8	0.7	-0.31	10.3	-8.1	-0.3	0.20
30a	-8.2	18.1	-0.3	0.24	10.4	9.4	0.7	-0.32	12.7	-10.5	-0.3	0.20
50a	-11.2	21.8	-0.6	0.28	13.7	10.9	1.0	-0.37	15.3	-14.0	-0.5	0.23
100a	-14.8	25.0	-1.5	0.42	17.4	11.9	1.7	-0.50	17.4	-18.2	-1.1	0.33
150a	-16.2	25.7	-2.3	0.55	18.6	11.9	2.4	-0.63	17.8	-19.9	-1.6	0.40
200a	-16.8	25.8	-3.0	0.68	19.2	11.8	3.0	-0.74	17.9	-20.6	-2.0	0.47
250a	-17.1	25.7	-3.7	0.80	19.4	11.6	3.6	-0.84	17.8	-21.0	-2.3	0.53
300a	-17.3	25.6	-4.4	0.92	19.6	11.5	4.1	-0.93	17.7	-21.2	-2.7	0.58
350a	-17.4	25.4	-5.1	1.03	19.7	11.3	4.5	-1.00	17.6	-21.3	-3.0	0.64
400a	-17.5	25.2	-5.6	1.13	19.8	11.2	4.9	-1.07	17.5	-21.3	-3.3	0.68
点位	玛多(34.916°N, 98.209°E)				称多(33.360°N, 97.104°E)				达日(33.750°N, 99.625°E)
	位移/mm			重力变化 /μGal	位移/mm			重力变化 /μGal	位移/mm			重力变化 /μGal
	经度方向	纬度方向	垂向		经度方向	纬度方向	垂向		经度方向	纬度方向	垂向
同震	-125.6	150.5	-3.0	4.98	8.3	6.4	3.0	-1.08	20.0	-23.2	-4.4	2.01
1a	-129.6	153.1	-3.6	5.08	9.3	7.4	2.9	-1.06	22.2	-25.1	-4.0	1.96
2a	-134.8	156.6	-4.4	5.22	10.7	8.8	2.7	-1.04	25.1	-27.8	-3.6	1.90
3a	-139.0	159.4	-4.9	5.31	12.1	9.9	2.5	-1.02	27.5	-30.1	-3.4	1.87
5a	-145.5	163.7	-5.6	5.42	14.5	11.9	2.4	-1.00	31.3	-33.9	-3.3	1.85
10a	-155.8	170.7	-5.5	5.39	19.5	15.3	2.3	-1.02	37.5	-41.0	-4.2	2.02
20a	-165.9	177.9	-2.8	4.86	26.0	18.6	3.2	-1.20	42.7	-48.9	-8.2	2.77
30a	-171.4	181.9	0.6	4.20	29.6	19.9	4.5	-1.45	44.4	-52.9	-12.8	3.63
50a	-178.0	186.9	7.4	2.93	33.2	20.6	7.5	-2.00	44.8	-56.7	-21.5	5.25
100a	-186.4	192.6	20.5	0.48	36.1	20.1	14.2	-3.24	43.9	-60.5	-37.9	8.32
150a	-190.6	195.0	29.2	-1.14	37.1	19.3	19.4	-4.20	43.5	-62.8	-48.5	10.31
200a	-193.0	196.3	35.2	-2.25	37.8	18.8	23.4	-4.93	43.5	-64.6	-55.5	11.61
250a	-194.5	197.1	39.4	-3.04	38.2	18.4	26.4	-5.48	43.6	-66.0	-60.2	12.49
300a	-195.5	197.6	42.5	-3.61	38.5	18.1	28.6	-5.90	43.8	-67.1	-63.4	13.09
350a	-196.2	197.9	44.8	-4.03	38.8	17.9	30.4	-6.22	44.0	-68.0	-65.7	13.51
400a	-196.7	198.2	46.5	-4.35	39.0	17.7	31.7	-6.47	44.1	-68.6	-67.3	13.82

Table2 The post-seismic effects on some of the cities

点位	德令哈(37.369°N, 97.356°E)				囊谦(32.208°N, 96.477°E)				阿坝(32.899°N, 101.706°E)
	位移/mm			重力变化 /μGal	位移/mm			重力变化 /μGal	位移/mm			重力变化 /μGal
	经度方向	纬度方向	垂向		经度方向	纬度方向	垂向		经度方向	纬度方向	垂向
同震	-1.8	3.2	-0.9	0.32	2.0	1.3	1.0	-0.32	2.0	-2.1	-0.8	0.26
1a	-2.0	3.8	-0.9	0.31	2.2	1.6	1.0	-0.32	2.4	-2.4	-0.7	0.25
2a	-2.2	4.6	-0.8	0.30	2.5	2.1	1.0	-0.32	3.0	-2.7	-0.7	0.25
3a	-2.4	5.3	-0.8	0.30	2.9	2.6	0.9	-0.32	3.5	-3.0	-0.7	0.25
5a	-2.9	6.8	-0.7	0.28	3.5	3.4	0.9	-0.32	4.5	-3.7	-0.6	0.24
10a	-4.0	10.0	-0.5	0.26	5.1	5.2	0.8	-0.31	6.8	-5.2	-0.4	0.22
20a	-6.2	14.8	-0.3	0.23	8.0	7.8	0.7	-0.31	10.3	-8.1	-0.3	0.20
30a	-8.2	18.1	-0.3	0.24	10.4	9.4	0.7	-0.32	12.7	-10.5	-0.3	0.20
50a	-11.2	21.8	-0.6	0.28	13.7	10.9	1.0	-0.37	15.3	-14.0	-0.5	0.23
100a	-14.8	25.0	-1.5	0.42	17.4	11.9	1.7	-0.50	17.4	-18.2	-1.1	0.33
150a	-16.2	25.7	-2.3	0.55	18.6	11.9	2.4	-0.63	17.8	-19.9	-1.6	0.40
200a	-16.8	25.8	-3.0	0.68	19.2	11.8	3.0	-0.74	17.9	-20.6	-2.0	0.47
250a	-17.1	25.7	-3.7	0.80	19.4	11.6	3.6	-0.84	17.8	-21.0	-2.3	0.53
300a	-17.3	25.6	-4.4	0.92	19.6	11.5	4.1	-0.93	17.7	-21.2	-2.7	0.58
350a	-17.4	25.4	-5.1	1.03	19.7	11.3	4.5	-1.00	17.6	-21.3	-3.0	0.64
400a	-17.5	25.2	-5.6	1.13	19.8	11.2	4.9	-1.07	17.5	-21.3	-3.3	0.68
点位	玛多(34.916°N, 98.209°E)				称多(33.360°N, 97.104°E)				达日(33.750°N, 99.625°E)
	位移/mm			重力变化 /μGal	位移/mm			重力变化 /μGal	位移/mm			重力变化 /μGal
	经度方向	纬度方向	垂向		经度方向	纬度方向	垂向		经度方向	纬度方向	垂向
同震	-125.6	150.5	-3.0	4.98	8.3	6.4	3.0	-1.08	20.0	-23.2	-4.4	2.01
1a	-129.6	153.1	-3.6	5.08	9.3	7.4	2.9	-1.06	22.2	-25.1	-4.0	1.96
2a	-134.8	156.6	-4.4	5.22	10.7	8.8	2.7	-1.04	25.1	-27.8	-3.6	1.90
3a	-139.0	159.4	-4.9	5.31	12.1	9.9	2.5	-1.02	27.5	-30.1	-3.4	1.87
5a	-145.5	163.7	-5.6	5.42	14.5	11.9	2.4	-1.00	31.3	-33.9	-3.3	1.85
10a	-155.8	170.7	-5.5	5.39	19.5	15.3	2.3	-1.02	37.5	-41.0	-4.2	2.02
20a	-165.9	177.9	-2.8	4.86	26.0	18.6	3.2	-1.20	42.7	-48.9	-8.2	2.77
30a	-171.4	181.9	0.6	4.20	29.6	19.9	4.5	-1.45	44.4	-52.9	-12.8	3.63
50a	-178.0	186.9	7.4	2.93	33.2	20.6	7.5	-2.00	44.8	-56.7	-21.5	5.25
100a	-186.4	192.6	20.5	0.48	36.1	20.1	14.2	-3.24	43.9	-60.5	-37.9	8.32
150a	-190.6	195.0	29.2	-1.14	37.1	19.3	19.4	-4.20	43.5	-62.8	-48.5	10.31
200a	-193.0	196.3	35.2	-2.25	37.8	18.8	23.4	-4.93	43.5	-64.6	-55.5	11.61
250a	-194.5	197.1	39.4	-3.04	38.2	18.4	26.4	-5.48	43.6	-66.0	-60.2	12.49
300a	-195.5	197.6	42.5	-3.61	38.5	18.1	28.6	-5.90	43.8	-67.1	-63.4	13.09
350a	-196.2	197.9	44.8	-4.03	38.8	17.9	30.4	-6.22	44.0	-68.0	-65.7	13.51
400a	-196.7	198.2	46.5	-4.35	39.0	17.7	31.7	-6.47	44.1	-68.6	-67.3	13.82

Fig. 7 Long-term time-varying effects after the earthquake.

Fig. 8 The distribution of the ratios between the viscoelastic relaxation effects during 400 years after the Maduo earthquake and the coseismic effects.

Fig. 9 The distribution of the ratios between the viscoelastic relaxation effects during 5 years after the Maduo earthquake and the coseismic effects.

Fig. 10 Comparison between the coseismic simulation and GNSS observation results.

References 38

[1]	戴华光. 1983. 1947年青海达日M7地震[J]. 西北地震学报, 5(3): 71-77.
	DAI Hua-guang. 1983. On the Dari earthquake of 1974 in Qinghai Province[J]. Northwestern Seismological Journal, 5(3): 71-77. (in Chinese)
[2]	贺鹏超, 王敏, 王琪, 等. 2018. 基于2001年M_W7.8可可西里地震震后形变模拟研究藏北地区岩石圈流变学结构[J]. 地球物理学报, 61(2): 531-544. doi: 10.6038/cjg2018L0189. DOI
	HE Peng-chao, WANG Min, WANG Qi, et al. 2018. Rheological structure of lithosphere in northern Tibet inferred from post-seismic deformation modeling of the 2001 M_W7.8 Kokoxili earthquake[J]. Chinese Journal of Geophysics, 61(2): 531-544. (in Chinese)
[3]	李陈侠, 徐锡伟, 闻学泽, 等. 2011. 东昆仑断裂带中东部地震破裂分段性与走滑运动分解作用[J]. 中国科学(D辑), 41(9): 1295-1310. doi: 10.1007/s11430-011-4239-5. DOI
	LI Chen-xia, XU Xi-wei, WEN Xue-ze, et al. 2011. Rupture segmentation and slip portioning of the mid-eastern part of the Kunlun Fault, north Tibetan plateau[J]. Science in China(Ser D), 41(9): 1295-1310. (in Chinese)
[4]	李传友, 宋方敏, 冉勇康. 2004. 龙门山断裂带北段晚第四纪活动性讨论[J]. 地震地质, 26(2): 248-258.
	LI Chuan-you, SONG Fang-min, RAN Yong-kang. 2004. Late Quaternary activity and age constraint of the northern Longmenshan fault zone[J]. Seismology and Geology, 26(2): 248-258. (in Chinese)
[5]	梁明剑, 杨耀, 杜方, 等. 2020. 青海达日断裂中段晚第四纪活动性与1947年M7.75地震地表破裂带再研究[J]. 地震地质, 42(3): 703-714. doi: 10.3969/j.issn.0253-4967.2020.03.011. DOI
	LIANG Ming-jian, YANG Yao, DU Fang, et al. 2020. Late Quaternary activity of the central segment of the Dari Fault and restudy of the surface rupture zone of the 1947 M7.75 Dari earthquake, Qinghai Province[J]. Seismology and Geology, 42(3): 703-714. (in Chinese)
[6]	梁明剑, 周荣军, 闫亮, 等. 2014. 青海达日断裂中段构造活动与地貌发育的响应关系探讨[J]. 地震地质, 36(1): 28-38. doi: 10.3969/j.issn.0253-4967.2014.01.003. DOI
	LIANG Ming-jian, ZHOU Rong-jun, YAN Liang, et al. 2014. The relationships between neotectonic activity of the middle segment of Dari Fault and its geomorphological response, Qinghai Province, China[J]. Seismology and Geology, 36(1): 28-38. (in Chinese)
[7]	刘刚, 王琪, 乔学军, 等. 2015. 用连续GPS与远震体波联合反演2015年尼泊尔中部M_S8.1地震破裂过程[J]. 地球物理学报, 58(11): 4287-4297. doi: 10.6038/cjg20151133. DOI
	LIU Gang, WANG Qi, QIAO Xue-jun, et al. 2015. The 25 April 2015 Nepal M_S81 earthquake slip distribution from joint inversion of teleseismic, static and high-rate GPS data[J]. Chinese Journal of Geophysics, 58(11): 4287-4297. (in Chinese)
[8]	青海省地震局, 中国地震局地壳应力研究所. 1999. 东昆仑活动断裂带[M]. 北京: 地震出版社:157-164.
	Qinghai Earthquake Administration, Institute of Crustal Dynamics, China Earthquake Administration. 1999. East Kunlun Active Fault Zone[M]. Seismological Press, Beijing:157-164. (in Chinese)
[9]	任金卫, 汪一鹏, 吴章明, 等. 1999. 青藏高原北部东昆仑断裂带第四纪活动特征和滑动速率 [G]//中国地震局地质研究所编编. 活动断裂研究. 北京: 地震出版社:147-163.
	REN Jin-wei, WANG Yi-peng, WU Zhang-ming, et al. 1999. Quaternary activity characteristics and slip rate of the East Kunlun fault zone in the northern Qinghai-Tibet Plateau [G]// Institute of Geology, China Earthquake Administration. Research on Active Faults. Seismological Press, Beijing:147-163. (in Chinese)
[10]	申重阳, 祝意青, 胡敏章, 等. 2020. 中国大陆重力场时变监测与强震预测[J]. 中国地震, 36(4): 729-743.
	SHEN Chong-yang, ZHU Yi-qing, HU Min-zhang, et al. 2020. Time-varying gravity field monitoring and strong earthquake prediction on the Chinese mainland[J]. Earthquake Research in China, 36(4): 729-743. (in Chinese)
[11]	孙文科. 2008. 地震火山活动产生重力变化的理论与观测研究的进展及现状[J]. 大地测量与地球动力学, 28(4): 44-53.
	SUN Wen-ke. 2008. Progress and current situation of research on theory and observation of gravity change caused by seismicity and volcanism[J]. Journal of Geodesy and Geodynamics, 28(4): 44-53. (in Chinese)
[12]	谈洪波, 申重阳, 李辉. 2008. 断层位错引起的地表重力变化特征研究[J]. 大地测量与地球动力学, 28(4): 54-62.
	TAN Hong-bo, SHEN Chong-yang, LI Hui. 2008. Characteristics of surface gravity changes caused by a fault or faults dislocation[J]. Journal of Geodesy and Geodynamics, 28(4): 54-62. (in Chinese)
[13]	谈洪波, 申重阳, 李辉, 等. 2009. 断层位错引起的地表形变特征[J]. 大地测量与地球动力学, 29(3): 42-49.
	TAN Hong-bo, SHEN Chong-yang, LI Hui, et al. 2009. Characteristics of surface deformation caused by fault dislocation[J]. Journal of Geodesy and Geodynamics, 29(3): 42-49. (in Chinese)
[14]	谈洪波, 申重阳, 邢乐林, 等. 2013. 玉树M_S7.1地震同震效应模拟与绝对重力检验[J]. 中国地震, 29(1): 116-123.
	TAN Hong-bo, SHEN Chong-yang, XING Le-lin, et al. 2013. Coseismic effect simulation of the Yushu M_S7.1 earthquake and absolute gravity inspection[J]. Earthquake Research in China, 29(1): 116-123. (in Chinese)
[15]	谈洪波, 申重阳, 玄松柏. 2010. 地壳分层和地壳厚度对汶川地震同震效应的影响[J]. 大地测量与地球动力学, 30(4): 29-35.
	TAN Hong-bo, SHEN Chong-yang, XUAN Song-bai. 2010. Influence of crust layering and thickness on coseismic effects of Wenchuan earthquake[J]. Journal of Geodesy and Geodynamics, 30(4): 29-35. (in Chinese)
[16]	隗寿春, 祝意青, 赵云峰, 等. 2020. 呼图壁M_S6.2地震前后重力变化特征分析[J]. 地震地质, 42(4): 923-935. doi: 10.3969/j.issn.0253-4967.2020.04.010. DOI
	WEI Shou-chun, ZHU Yi-qing, ZHAO Yun-feng, et al. 2020. Study on characteristics of gravity variation before and after Hutubi M_S6.2 earthquake[J]. Seismology and Geology, 42(4): 923-935. (in Chinese)
[17]	闻学泽, 徐锡伟, 郑荣章, 等. 2003. 甘孜-玉树断裂的平均滑动速率与近代大地震破裂[J]. 中国科学(D辑), 33(S1): 199-208.
	WEN Xue-ze, XU Xi-wei, ZHENG Rong-zhang, et al. 2003. The average slip rate of the Ganzi-Yushu Fault and the rupture area of large earthquakes in modern times[J]. Science in China(Ser D), 33(S1): 199-208. (in Chinese)
[18]	熊仁伟, 任金卫, 张军龙, 等. 2010. 玛多-甘德断裂甘德段晚第四纪活动特征[J]. 地震, 30(4): 65-73.
	XIONG Ren-wei, REN Jin-wei, ZHANG Jun-long, et al. 2010. Late Quaternary active characteristics of the Gande segment in the Maduo-Gande fault zone[J]. Earthquake, 30(4): 65-73. (in Chinese)
[19]	张晁军, 曹建玲, 石耀霖. 2008. 从震后形变探讨青藏高原下地壳黏滞系数[J]. 中国科学(D辑), 38(10): 1250-1257.
	ZHANG Chao-jun, CAO Jian-ling, SHI Yao-lin. 2008. Discussion on the viscosity coefficient of the lower crust of the Qinghai-Tibet Plateau from post-earthquake deformation[J]. Science in China(Ser D), 38(10): 1250-1257. (in Chinese)
[20]	张裕明, 李闽峰, 孟勇琦, 等. 1996. 巴颜喀拉山地区断层活动性研究及其地震地质意义 [G]//国家地震局地质研究所编编. 活动断裂研究. 北京: 地震出版社:154-171.
	ZHANG Yu-ming, LI Min-feng, MENG Yong-qi, et al. 1996. Research on fault activities and their seismogeological implication in Bayankala mountain area [G]// Institute of Geology, China Earthquake Administration. Research on Active Faults. Seismological Press, Beijing:154-171. (in Chinese)
[21]	赵斌, 王敏, 胡岩, 等. 2020. 中国及邻域强震震后变形监测及岩石流变性质研究[J]. 中国地震, 36(4): 806-816.
	ZHAO Bin, WANG Min, HU Yan, et al. 2020. Rock rheology and observation of postseismic deformation following strong earthquake in China and its surrounding region[J]. Earthquake Research in China, 36(4): 806-816. (in Chinese)
[22]	祝意青, 刘芳, 李铁明, 等. 2015. 川滇地区重力场动态变化及其强震危险含义[J]. 地球物理学报, 58(11): 4187-4196. doi: 10.6038/cjg20151125. DOI
	ZHU Yi-qing, LIU Fang, LI Tie-ming, et al. 2015. Dynamic variation of the gravity field in the Sichuan-Yunnan region and its implication for seismic risk[J]. Chinese Journal of Geophysics, 58(11): 4187-4196. (in Chinese)
[23]	Feng W, Lindsey E, Barbot S, et al. 2017. Source characteristics of the 2015 M_W7.8 Gorkha(Nepal)earthquake and its M_W7.2 aftershock from space geodesy[J]. Tectonophysics, 713(8): 747-758. doi: 10.1016/j.tecto.2016.02.029. DOI
[24]	Fung Y C. 1965. Foundations of Solid Mechanics[M]. Prentice Hall, Englewood Cliffs, NJ:525.
[25]	Haskell N A. 1953. The dispersion of surface waves on multilayered media[J]. Bulletin of the Seismological Society of America, 43(1): 17-34. DOI URL
[26]	Kind R, Seidl D. 1982. Analysis of broadband seismograms from the Chile-Peru area[J]. Bulletin of the Seismological Society of America, 72(6A): 2131-2145. DOI URL
[27]	Longman I M. 1963. A Green’s function for determining the deformation of the Earth under surface loads Ⅱ: Computations and numerical results[J]. Journal of Geophysical Research, 68(2): 485-496. DOI URL
[28]	Matsuura M, Tanimoto T, Iwasaki T. 1981. Quasi-static displacements due to faulting in a layered half-space with an intervenient viscoelastic layer[J]. Journal of Physics of the Earth, 29(1): 23-54. DOI URL
[29]	Okada Y. 1985. Surface deformation due to shear and tensile faults in a half-space[J]. Bulletin of the Seismological Society of America, 75(4): 1135-1154. DOI URL
[30]	Okubo S. 1992. Gravity and potential changes due to shear and tensile faults in a half-space[J]. Journal of Geophysical Research, 97(B5): 7137-7144. DOI URL
[31]	Pollitz F F. 1996. Coseismic deformation from earthquake faulting in a layered spherical Earth[J]. Geophysical Journal International, 125(1): 1-4. DOI URL
[32]	Riguzzi F, Tan H, Shen C. 2019. Surface volume and gravity changes due to significant earthquakes occurred in central Italy from 2009 to 2016 [J]. International Journal of Earth Sciences. 108(6): 2047-2056. doi: 10.1007/s00531-019-01748-0. DOI URL
[33]	Rundle J B. 1980. Static elastic-gravitational deformation of a layered half space by point couple sources[J]. Journal of Geophysical Research, 85(B10): 5355-5363. DOI URL
[34]	Sun W, Okubo S. 2002. Effects of the earth’s spherical curvature and radial heterogeneity in dislocation studies for a point dislocation[J]. Geophysical Research Letters, 29(12): 461-464.
[35]	Wang H. 1999. Surface vertical displacements, potential perturbations and gravity changes of a viscoelastic earth model induced by internal point dislocations[J]. Geophysical Journal International, 137(2): 429-440. DOI URL
[36]	Wang R, Lorenzo-Martin F, Roth F. 2006. PSGRN/PSCMP: A new code for calculating co- and post-seismic deformation, geoid and gravity changes based on the viscoelastic-gravitational dislocation theory[J]. Computers and Geosciences, 32(4): 527-541. DOI URL
[37]	Zhang R, Wang R, Zschau J, et al. 2014. Automatic imaging of earthquake rupture processes by iterative deconvolution and stacking of high-rate GPS and strong motion seismograms[J]. Journal of Geophysical Research: Solid Earth, 119(7): 5633-5650. doi: /10.1002/2013JB010469. DOI URL
[38]	Zhang X, Okubo S, Tanaka Y, et al. 2016. Coseismic gravity and displacement changes of Japan Tohoku earthquake(M_W9.0)[J]. Geodesy and Geodynamics, 7(2): 95-100. doi: 10.1016/j.geog.2015.10.002. DOI URL