PRELIMINARY STUDY ON THE SEISMOGENIC STRUCTURE OF THE 2024 M5 EARTHQUAKE SWARM IN YULI, TARIM BASIN

doi:10.3969/j.issn.0253-4967.2025.02.20250064

SEISMOLOGY AND GEOLOGY ›› 2025, Vol. 47 ›› Issue (2): 463-487.DOI: 10.3969/j.issn.0253-4967.2025.02.20250064

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PRELIMINARY STUDY ON THE SEISMOGENIC STRUCTURE OF THE 2024 M5 EARTHQUAKE SWARM IN YULI, TARIM BASIN

LI Jin¹^,²^,³⁾(), DENG Ming-wen⁴⁾, ZHANG Zhi-guang⁵⁾, SUN Ye-jun³^,⁶⁾^,^*(), YAO Yuan¹^,²^,³⁾, XU Kai-chi⁷⁾

¹⁾ Xinjiang Pamir Intracontinental Subduction National Observation and Research Station, Urumqi 830011, China
²⁾ Earthquake Agency of Xinjiang Uygur Autonomous Region, Urumqi 830011, China
³⁾ Urumqi Institute of Central Asia Earthquake, China Earthquake Administration, Urumqi 830011, China
⁴⁾ Korla Earthquake Monitoring Center Station, Korla 841000, China
⁵⁾ School of Mining Engineering and Geology, Xinjiang Institute of Engineering, Urumqi 830023, China
⁶⁾ Earthquake Administration of Jiangsu Province, Nanjing 210014, China
⁷⁾ Tarim Oil field Company, PetroChina, Xinjiang, Korla 841000, China

Received:2025-03-07 Revised:2025-03-17 Online:2025-04-20 Published:2025-06-07

2024年塔里木盆地尉犁5级震群发震构造

李金¹^,²^,³⁾(), 邓明文⁴⁾, 张治广⁵⁾, 孙业君³^,⁶⁾^,^*(), 姚远¹^,²^,³⁾, 徐凯驰⁷⁾

¹⁾ 新疆帕米尔陆内俯冲国家野外科学观测研究站, 乌鲁木齐 830011
²⁾ 新疆维吾尔自治区地震局, 乌鲁木齐 830011
³⁾ 中国地震局乌鲁木齐中亚地震研究所, 乌鲁木齐 830011
⁴⁾ 库尔勒地震监测中心站, 库尔勒 841000
⁵⁾ 新疆工程学院矿业工程与地质学院, 乌鲁木齐 830023
⁶⁾ 江苏省地震局, 南京 210014
⁷⁾ 中国石油塔里木油田分公司勘探开发研究院, 库尔勒 841000

通讯作者: * 孙业君, 男, 1979年生, 正高级工程师, 主要从事数字地震学及地震预测研究, E-mail: syj_4116@126.com。
作者简介:
李金, 男, 1986年生, 2012年于中国地震局地震预测研究所获固体地球物理专业硕士学位, 高级工程师, 主要从事数字地震学及地震预测研究工作, E-mail: lijin6205@163.com。
基金资助:
新疆维吾尔自治区重点研发计划(2024B03018-3); 江苏省重点研发计划产业前瞻与关键核心技术(BE2023082); 中国地震局地震科技星火计划项目(XH21042); 中国地震局地震预测研究所基本科研业务专项(CEAIEF20230203)

Abstract

Abstract:

The Tarim Basin, a typical small cratonic basin and the largest inland basin in China, is bordered by three major orogenic belts: the Kunlun, Altun, and Tianshan Mountains. Prior to 2000, seismic activity within the basin was sparse. However, with the ongoing development of oil and gas exploration and extraction after 2000, seismicity began to increase, forming a distinct pattern of earthquake swarms—referred to as the Tarim earthquake swarm. Notably, since 2017, both the frequency and magnitude of earthquakes have risen significantly. Major events include the Kuqa M5.6 earthquake on January 16, 2020, the Shaya M6.1 earthquake on January 30, 2023, and three M5.0 earthquakes in the Yuli-Kuqa area in 2024. The rising seismicity has drawn increasing attention, particularly due to heightened activity in the Yuli region since June 2024, now considered the most seismically active area in both Xinjiang and China.
This study applies the Cut and Paste(CAP)method to invert focal mechanisms for three M5.0 earthquakes and other events above M_L4.0 within the Yuli earthquake swarm. The double-difference relocation method was employed to refine the hypocentral locations of earthquakes above M_L2.0. Furthermore, by analyzing the spatial distribution of smaller events and modeling the regional stress field, the study infers plausible parameters for seismogenic fault planes and investigates the faults responsible for the swarm. Among the 44 earthquakes analyzed, 42 exhibit strike-slip focal mechanisms. Cluster analysis reveals the presence of nearly north-south(NS)oriented nodal planes, consistent with regional strike-slip faulting trends in the NS to NNE direction. The relocated seismic sequence shows a clear division into eastern and western branches, both exhibiting linear NNE-trending patterns. Initially, seismic activity was concentrated in the eastern segment, but both branches demonstrated a northward migration over time. Based on the focal mechanisms, relocation data, and inferred fault plane parameters—combined with known fault structures in the region—it is preliminarily concluded that the Yuli earthquake swarm occurred along two nearly parallel, NNE-trending, right-lateral strike-slip faults: F₁(east)and F₂(west). Both faults are nearly vertical, with F₁ exhibiting a steeper dip. The fault depths are estimated at 20~25km. The previously mapped faults F_Ⅰ18 and F_Ⅰ16 near the Yuli swarm may correspond to the shallow and deep sections of faults F₁ and F₂, respectively. The eastern fault(F_Ⅰ18/F₁) maintains consistent dip characteristics from shallow to deep levels, whereas the western fault(F_Ⅰ16/F₂)displays a gentler dip at depth compared to the surface.
In addition to the Yuli swarm, the Tarim Basin has recently experienced the 2012 Luopu M6.0 earthquake(thrust)and the 2023 Shaya M6.1 earthquake(strike-slip), reflecting diverse faulting mechanisms driven by a common regional tectonic regime. The Luopu event resulted from thrusting of the Bachu Uplift toward the Awati Depression, induced by the ongoing convergence of the Indian and Eurasian plates. In contrast, the Shaya earthquake and the Yuli swarm likely represent secondary strike-slip structures accommodating crustal deformation from northward-directed compressive stress associated with NW- and EW-trending thrust belts in the basin interior. The Yuli earthquake swarm is located in the Yuke region of eastern Tarim, an area rich in oil and gas resources. In recent years, extraction activities have intensified, raising questions about a potential link between these activities and the increased seismicity. Further investigation is required to clarify the relationship between industrial activity and the occurrence of the Yuli earthquake swarm.

Key words: The Tarim Basin, Yuli earthquake swarm, focal mechanism solution, relocation, NNE-trending strike-slip faults

摘要：

2024年6月以来, 塔里木盆地内部尉犁地区地震活动异常活跃, 是新疆甚至中国地震活动最主要的地区。文中采用CAP方法反演了尉犁震群中3次5级地震及M_L4.0以上地震的震源机制; 采用双差定位方法对该震群中M_L2.0以上地震进行了重新定位, 并利用小地震分布和区域应力场拟合了可能的发震断层面参数, 在此基础上分析了震群活动可能的发震断层。结果显示, 44次地震中有42次为走滑型, 经聚类分析均存在近SN向的节面, 与震中附近近SN向或NNE向分布的走滑断裂特征较为一致。重新定位后的震群序列明显分为东、西2支, 且均呈现NNE向线性分布特征。震群早期地震主要集中在东区, 随着时间的推移, 东区和西区地震均呈现向N迁移的特征。根据序列震源机制、重定位结果及利用小地震约束得到的断层面参数, 结合震区的断层信息, 初步推断此次尉犁震群发生在近平行的NNE向右旋走滑断裂F₁(东区)和F₂(西区)上, 2条断裂均呈近直立(略微W倾)特征, 且F₁较F₂断层面更陡, 断裂深度可达20~25km。尉犁震群附近已知的断裂F_Ⅰ18和F_Ⅰ16与F₁和F₂断裂可能分别对应震区附近走滑断裂的浅部和深部, 其中东区断裂(F_Ⅰ18和F₁)深、浅部的产状特征基本一致, 而西区断裂(F_Ⅰ16和F₂)深部的倾角较浅部更小。受印度板块对欧亚板块的推挤, 塔里木震群区的一系列走滑断裂成为盆地中部NW向和近EW向大型逆冲带向N推挤时形成的伴生调节构造, 是调节区域挤压缩短变形的代表性构造样式。此外尉犁震群位于塔里木盆地东部的玉科地区, 该区油气资源相对富集, 此次震群是否与油气开采相关仍需进一步考证。

关键词: 塔里木盆地, 尉犁5级震群, 震源机制解, 重新定位, NNE向走滑断裂

LI Jin, DENG Ming-wen, ZHANG Zhi-guang, SUN Ye-jun, YAO Yuan, XU Kai-chi. PRELIMINARY STUDY ON THE SEISMOGENIC STRUCTURE OF THE 2024 M5 EARTHQUAKE SWARM IN YULI, TARIM BASIN[J]. SEISMOLOGY AND GEOLOGY, 2025, 47(2): 463-487.

李金, 邓明文, 张治广, 孙业君, 姚远, 徐凯驰. 2024年塔里木盆地尉犁5级震群发震构造[J]. 地震地质, 2025, 47(2): 463-487.

Figures/Tables 12

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深度/km	P波速度/km·s^-1	V_P/V_S
0	0.937	1.75
0.3	1.576
1	1.963
2.5	2.444
4.2	2.75
8	3.457
15	5.104
20	5.426
30	6.38
40	6.825
50	7.924

深度/km	P波速度/km·s^-1	V_P/V_S
0	0.937	1.75
0.3	1.576
1	1.963
2.5	2.444
4.2	2.75
8	3.457
15	5.104
20	5.426
30	6.38
40	6.825
50	7.924

发震时刻 (北京时间)	震级 M_S	震级 M_W	CAP 深度 /km	节面Ⅰ			节面Ⅱ			最小空间旋转角 /(°)	震源球	来源
发震时刻 (北京时间)	震级 M_S	震级 M_W	CAP 深度 /km	走向 /(°)	倾角 /(°)	滑动角 /(°)	走向 /(°)	倾角 /(°)	滑动角 /(°)	最小空间旋转角 /(°)	震源球	来源
2024-06-11 01:35	5.0	4.65	11	279	70	11	185	80	160			本文
		5.0	14	99	79	-10	191	80	-169	37.3		GlobalCMT ^①
		4.7	23	283	83	21	191	69	173	16.3		地球物理研究所 ^②
		4.9	10	280	86	23	188	67	176	19.8		梁姗姗等(2024)
2024-08-22 07:38	5.0	4.57	7	201	28	161	308	81	63			本文
		4.5	26	181	51	146	294	64	44	26.05		地球物理研究所 ^③
		4.7	16	207	88	175	297	85	2	60.9		梁姗姗等(2025)
2024-10-26 16:35	5.5	4.81	7	82	68	-3	173	87	-158			本文
		5.1	17.7	82	74	-14	176	76	-163	12.5		GlobalCMT ^①
		4.8	23	266	69	12	174	78	158	45		地球物理研究所 ^④
		5.1	9	263	87	6	173	84	177	25.2		梁姗姗等(2025)

发震时刻 (北京时间)	震级 M_S	震级 M_W	CAP 深度 /km	节面Ⅰ			节面Ⅱ			最小空间旋转角 /(°)	震源球	来源
发震时刻 (北京时间)	震级 M_S	震级 M_W	CAP 深度 /km	走向 /(°)	倾角 /(°)	滑动角 /(°)	走向 /(°)	倾角 /(°)	滑动角 /(°)	最小空间旋转角 /(°)	震源球	来源
2024-06-11 01:35	5.0	4.65	11	279	70	11	185	80	160			本文
		5.0	14	99	79	-10	191	80	-169	37.3		GlobalCMT ^①
		4.7	23	283	83	21	191	69	173	16.3		地球物理研究所 ^②
		4.9	10	280	86	23	188	67	176	19.8		梁姗姗等(2024)
2024-08-22 07:38	5.0	4.57	7	201	28	161	308	81	63			本文
		4.5	26	181	51	146	294	64	44	26.05		地球物理研究所 ^③
		4.7	16	207	88	175	297	85	2	60.9		梁姗姗等(2025)
2024-10-26 16:35	5.5	4.81	7	82	68	-3	173	87	-158			本文
		5.1	17.7	82	74	-14	176	76	-163	12.5		GlobalCMT ^①
		4.8	23	266	69	12	174	78	158	45		地球物理研究所 ^④
		5.1	9	263	87	6	173	84	177	25.2		梁姗姗等(2025)

PRELIMINARY STUDY ON THE SEISMOGENIC STRUCTURE OF THE 2024 M5 EARTHQUAKE SWARM IN YULI, TARIM BASIN

2024年塔里木盆地尉犁5级震群发震构造

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[14]	WANG Liang, JIAO Ming-ruo, QIAN Rui, ZHANG Bo, YANG Shi-chao, SHAO Yuan-yuan. CRUSTAL VELOCITY STRUCTURE BENEATH THE SOUTHERN LIAONING PROVINCE DERIVED FROM DOUBLE DIFFERENCE TOMOGRAPHY [J]. SEISMOLOGY AND GEOLOGY, 2022, 44(2): 378-394.
[15]	YU Zhan-yang, SHEN Xu-zhang, LIANG Hao, ZHENG Wen-jun, LIU Xu-zhou. THE CHARACTERISTICS OF MAJOR FAULTS AND STRESS FIELD IN WEIHE-YUNCHENG BASIN CONSTRAINED BY SEISMIC ACTIVITY AND FOCAL MECHANISM SOLUTIONS [J]. SEISMOLOGY AND GEOLOGY, 2022, 44(2): 395-413.

序号	发震时刻 (北京时间)	震级	震级 M_W	CAP深度 /km	节面Ⅰ					节面Ⅱ
					走向 /(°)	倾角 /(°)	滑动角 /(°)	走向 /(°)	倾角 /(°)	滑动角 /(°)
1	2024-06-11,01:35	M_S5.0	4.65	11	279	70	11	185	80	160
2	2024-06-20,00:59	M_L4.6	3.84	11	10	81	-150	275	60	-10
3	2024-06-23,23:36	M_L4.2	3.73	15	277	80	17	184	73	170
4	2024-06-24,13:36	M_L5.3	4.57	10	279	68	9	186	82	158
5	2024-06-25,13:25	M_L4.0	3.57	17	303	50	-10	39	82	-140
6	2024-07-03,14:10	M_L4.2	3.68	11	200	80	160	294	70	11
7	2024-07-05,06:04	M_L5.0	4.43	14	9	90	-169	279	79	0
8	2024-07-10,21:34	M_L4.3	3.87	9	290	54	-24	35	71	-142
9	2024-07-12,09:56	M_L4.1	3.52	11	33	63	-151	289	64	-30
10	2024-07-12,22:35	M_L4.1	3.47	13	106	90	-29	196	61	-180
11	2024-07-15,05:58	M_L4.3	3.95	13	28	90	-170	298	80	0
12	2024-07-17,01:29	M_L4.2	3.57	15	209	65	-171	115	82	-25
13	2024-07-20,09:56	M_L4.8	4.14	14	300	82	8	209	82	172
14	2024-07-20,22:18	M_L5.2	4.29	15	180	81	171	271	81	9
15	2024-07-24,16:39	M_L4.7	4.28	7	20	90	158	110	68	0
16	2024-07-25,09:27	M_L4.0	3.51	22	11	84	-150	278	60	-7
17	2024-08-03,05:19	M_L4.4	3.92	9	108	79	-46	209	45	-164
18	2024-08-14,09:34	M_L4.3	3.75	14	11	81	-173	280	83	-9
19	2024-08-14,09:36	M_L4.8	4.48	21	299	80	20	205	70	169
20	2024-08-22,07:38	M_S5.0	4.57	7	201	28	161	308	81	63
21	2024-09-15,16:17	M_L5.0	4.38	16	94	90	-12	184	78	-180
22	2024-09-23,12:30	M_L4.3	3.76	21	271	68	13	176	78	157
23	2024-09-26,06:41	M_L4.2	3.76	20	191	85	168	282	78	5
24	2024-09-26,23:02	M_L4.5	3.85	11	102	82	-11	194	79	-172
25	2024-10-02,12:08	M_L4.1	3.81	20	289	71	8	196	82	161
26	2024-10-02,16:18	M_L4.4	3.92	14	17	90	-158	287	68	0
27	2024-10-02,19:08	M_L4.3	3.81	20	191	83	164	283	74	7
28	2024-10-13,01:06	M_L4.3	3.75	11	101	74	-14	195	77	-164
29	2024-10-13,07:22	M_L4.2	3.99	21	99	59	-10	194	81	-149
30	2024-10-13,07:30	M_L4.8	4.31	15	100	65	-5	192	85	-155
31	2024-10-13,09:01	M_L4.1	3.86	22	179	79	161	273	71	12
32	2024-10-14,21:30	M_L4.4	3.91	9	280	81	10	188	80	171
33	2024-10-15,01:07	M_L4.2	3.62	9	268	78	11	176	79	168
34	2024-10-16,19:39	M_L4.3	3.96	12	280	76	7	188	83	166
35	2024-10-16,19:43	M_L5.2	4.28	11	99	80	-12	191	78	-170
36	2024-10-16,22:00	M_L4.3	3.77	24	180	75	139	283	51	20
37	2024-10-20,05:04	M_L4.1	3.70	20	17	81	-165	285	75	-9
38	2024-10-21,21:53	M_L4.0	3.70	19	23	81	169	115	79	9
39	2024-10-22,06:40	M_L4.1	3.63	7	280	58	23	177	71	146

序号	发震时刻 (北京时间)	震级	震级 M_W	CAP深度 /km	节面Ⅰ					节面Ⅱ
					走向 /(°)	倾角 /(°)	滑动角 /(°)	走向 /(°)	倾角 /(°)	滑动角 /(°)
1	2024-06-11,01:35	M_S5.0	4.65	11	279	70	11	185	80	160
2	2024-06-20,00:59	M_L4.6	3.84	11	10	81	-150	275	60	-10
3	2024-06-23,23:36	M_L4.2	3.73	15	277	80	17	184	73	170
4	2024-06-24,13:36	M_L5.3	4.57	10	279	68	9	186	82	158
5	2024-06-25,13:25	M_L4.0	3.57	17	303	50	-10	39	82	-140
6	2024-07-03,14:10	M_L4.2	3.68	11	200	80	160	294	70	11
7	2024-07-05,06:04	M_L5.0	4.43	14	9	90	-169	279	79	0
8	2024-07-10,21:34	M_L4.3	3.87	9	290	54	-24	35	71	-142
9	2024-07-12,09:56	M_L4.1	3.52	11	33	63	-151	289	64	-30
10	2024-07-12,22:35	M_L4.1	3.47	13	106	90	-29	196	61	-180
11	2024-07-15,05:58	M_L4.3	3.95	13	28	90	-170	298	80	0
12	2024-07-17,01:29	M_L4.2	3.57	15	209	65	-171	115	82	-25
13	2024-07-20,09:56	M_L4.8	4.14	14	300	82	8	209	82	172
14	2024-07-20,22:18	M_L5.2	4.29	15	180	81	171	271	81	9
15	2024-07-24,16:39	M_L4.7	4.28	7	20	90	158	110	68	0
16	2024-07-25,09:27	M_L4.0	3.51	22	11	84	-150	278	60	-7
17	2024-08-03,05:19	M_L4.4	3.92	9	108	79	-46	209	45	-164
18	2024-08-14,09:34	M_L4.3	3.75	14	11	81	-173	280	83	-9
19	2024-08-14,09:36	M_L4.8	4.48	21	299	80	20	205	70	169
20	2024-08-22,07:38	M_S5.0	4.57	7	201	28	161	308	81	63
21	2024-09-15,16:17	M_L5.0	4.38	16	94	90	-12	184	78	-180
22	2024-09-23,12:30	M_L4.3	3.76	21	271	68	13	176	78	157
23	2024-09-26,06:41	M_L4.2	3.76	20	191	85	168	282	78	5
24	2024-09-26,23:02	M_L4.5	3.85	11	102	82	-11	194	79	-172
25	2024-10-02,12:08	M_L4.1	3.81	20	289	71	8	196	82	161
26	2024-10-02,16:18	M_L4.4	3.92	14	17	90	-158	287	68	0
27	2024-10-02,19:08	M_L4.3	3.81	20	191	83	164	283	74	7
28	2024-10-13,01:06	M_L4.3	3.75	11	101	74	-14	195	77	-164
29	2024-10-13,07:22	M_L4.2	3.99	21	99	59	-10	194	81	-149
30	2024-10-13,07:30	M_L4.8	4.31	15	100	65	-5	192	85	-155
31	2024-10-13,09:01	M_L4.1	3.86	22	179	79	161	273	71	12
32	2024-10-14,21:30	M_L4.4	3.91	9	280	81	10	188	80	171
33	2024-10-15,01:07	M_L4.2	3.62	9	268	78	11	176	79	168
34	2024-10-16,19:39	M_L4.3	3.96	12	280	76	7	188	83	166
35	2024-10-16,19:43	M_L5.2	4.28	11	99	80	-12	191	78	-170
36	2024-10-16,22:00	M_L4.3	3.77	24	180	75	139	283	51	20
37	2024-10-20,05:04	M_L4.1	3.70	20	17	81	-165	285	75	-9
38	2024-10-21,21:53	M_L4.0	3.70	19	23	81	169	115	79	9
39	2024-10-22,06:40	M_L4.1	3.63	7	280	58	23	177	71	146