西昆仑山前固满背斜带弯矩正断层活动特征及其形成机制

doi:10.3969/j.issn.0253-4967.2025.02.20240148

地震地质 ›› 2025, Vol. 47 ›› Issue (2): 405-428.DOI: 10.3969/j.issn.0253-4967.2025.02.20240148

西昆仑山前固满背斜带弯矩正断层活动特征及其形成机制

许建红¹^,²⁾(), 陈杰¹⁾, 李涛¹⁾, 张博譞¹⁾, 邸宁¹⁾

¹⁾ 新疆帕米尔陆内俯冲国家野外科学观测研究站, 地震动力学与强震预测全国重点实验室(中国地震局地质研究所), 北京 100029
²⁾ 中国地震局第二监测中心, 西安 710054

收稿日期:2024-12-01 修回日期:2025-01-18 出版日期:2025-06-07 发布日期:2025-06-07
作者简介:
许建红, 男, 1983年生, 2022年于中国地震局地质研究所获构造地质学专业理学博士学位, 高级工程师, 主要从事活动构造研究、地震安全性评价等工作, E-mail: xujianhongmailbox@163.com。
基金资助:
国家重点研发计划项目(2022YFC3003700); 陕西省自然科学基础研究计划项目(2023-JC-YB-260); 国家自然科学基金(41802229); 国家自然科学基金(41772221)

DENSE BENDING MOMENT NORMAL FAULT SCARPS ALONG THE GUMAN ANTICLINE AT THE FOOTHILL OF THE WEST KUNLUN MOUNTAINS

XU Jian-hong¹^,²⁾(), CHEN Jie¹⁾, LI Tao¹⁾, ZHANG Bo-xuan¹⁾, DI Ning¹⁾

¹⁾ Institute of Geology, China Earthquake Administration; Xinjiang Pamir Intracontinental Subduction National Observation and Research Station; State Key Laboratory of Earthquake Dynamics and Forecasting, Institute of Geology, China Earthquake Administration, Beijing 100029, China
²⁾ The Second Monitoring and Application Center, CEA, Xi’an 710054, China

Received:2024-12-01 Revised:2025-01-18 Online:2025-06-07 Published:2025-06-07

摘要/Abstract

摘要：

弯矩断层和弯滑断层是挤压构造环境下常见的2种褶皱相关断层。历史地震表明这些断层会同步活动, 其地表陡坎蕴含着强震活动信息。西昆仑山前固满背斜带北部发育了众多壮观的弯矩正断层陡坎, 坎高0.5~16.0m。文中以一段长约5.4km、宽约4.2km的断层陡坎带为研究对象, 通过无人机摄影测量, 获取了该区域0.2m分辨率的数字高程模型(DEM), 并提取了739条跨断层陡坎地形剖面, 计算了陡坎的高度、坡度参数, 获得了沿断层位移和最大坡度的连续剖面及累积位移剖面。分析表明: 1)弯矩正断层沿着背斜轴大体平行展布, 将阶地面切成了多个条形地块。这些地块在断层活动过程中向背斜轴外侧掀斜, 其掀斜程度和断层位移量受下伏背斜地层厚度和地层弯曲程度控制。研究区坡向N的弯矩正断层陡坎有十几条, 仅在最北侧发育了1、 2条坡向S的陡坎, 形成不对称的地堑, 这可能与研究区地层整体向N倾斜和下伏背斜两翼不对称发育有关。2)单条、分组和累积断层位移剖面沿走向随阶地变年轻呈现“台阶”状降低, 最大坡度与位移剖面变化的特征相似, 表明研究区的弯矩正断层是长期活动的。不同阶地面上的累积位移量比值暗示, 断层带活动可能先形成了框架断层, 后穿插了一些新生断层。3)研究区的弯矩正断层为浅地表的次级断层, 无根但长期活动, 指示了下伏褶皱的背形断弯也是活动的, 支持固满背斜为活动断弯褶皱的观点。

Abstract:

Bending-moment fault and flexural-slip fault are two types of fold-related faults in compressional tectonic environments. Historical earthquake records suggest that both fault types may be active simultaneously, with their fault scarps providing crucial insights into strong seismic events. In the northern region of the Guman anticline, located at the foothills of the West Kunlun Mountains, numerous prominent bending-moment normal fault scarps have developed, reaching heights between 0.5m and 16.0m. This study focuses on a fault scarp segment approximately 5.4km long and 4.2km wide. A digital elevation model(DEM)with a 0.2m resolution was generated using drone photogrammetry. A total of 739 cross-fault scarp profiles were extracted, providing key parameters such as scarp height, slope, displacement continuity, and cumulative displacement trends. Data analysis yielded the following findings:
(1)In the study area, dense bending-moment normal faults align along the active anticline axis, dipping toward the axial plane at angle of 70°~80°, as observed in a trench. Among these faults, more than a dozen dip northward, whereas only 1-2 dip southward, forming asymmetric grabens. This asymmetry may be attributed to the overall northward tilt of the strata and the differing limb structures of the underlying anticline. These faults divide the terrace surfaces into multiple rectangular blocks, 380~650m wide. The blocks exhibit outward tilting relative to the fold axis, with those cut by north-dipping faults tilting southward and those cut by south-dipping faults tilting northward. The degree of tilting and fault displacement is closely related to the thickness of the underlying anticlinal strata and the extent of stratal bending.
(2)Displacement profiles along the faults reveal a step-like decrease in displacement as terrace surfaces become progressively younger, with maximum slope profiles displaying similar trends. This pattern suggests long-term fault activity. Cumulative displacement data confirm this trend, with displacement values of(54.5±3.3)m for terrace T3c and(19.5±1.1)m for terrace T1c. The total displacement of T3c is approximately 2.8 times that of T1c, and displacement ratios across different terraces range from 1.5 to 5.5. Higher ratios indicate greater displacement accumulation on older terraces, suggesting an earlier onset of fault activity. These displacement rankings imply that an initial framework of faults developed in the region, followed by subsequent fault intrusion. Notably, Fault F₈ exhibits a displacement ratio of 5.5, forming a(1.0±0.3)m high fault scarp on the young T1b terrace, indicating that even the earliest-formed faults remain active.
(3)Seismic reflection profiles reveal that the south flank of the Guman anticline dips 3°~6° northward, while the north flank dips 12°~14° northward. The underlying blind thrust exhibits a lower flat-ramp-upper flat geometry. However, bending-moment normal faults are not visible in the seismic reflection data, suggesting that they are secondary structures associated with anticline deformation. The fault zone aligns with the anticline’s fault-bend axis, indicating ongoing activity in the anticline zone. The bending-moment normal faults are rootless, meaning they are not primary seismogenic faults. Instead, they primarily develop in poorly layered strata and are largely independent of the kinematics of fold growth. Their formation is closely tied to the degree of strata bending and the thickness of overlying beds. Despite their shallow nature, the bending-moment normal faults exhibit long-term activity, providing evidence that the underlying anticline remains active. These findings support the interpretation of the Guman anticline as an active fault-bend fold.

Key words: Guman anticline, fold-related faults, bending-moment normal faults, fault scarps, compressional tectonic environment

许建红, 陈杰, 李涛, 张博譞, 邸宁. 西昆仑山前固满背斜带弯矩正断层活动特征及其形成机制[J]. 地震地质, 2025, 47(2): 405-428.

XU Jian-hong, CHEN Jie, LI Tao, ZHANG Bo-xuan, DI Ning. DENSE BENDING MOMENT NORMAL FAULT SCARPS ALONG THE GUMAN ANTICLINE AT THE FOOTHILL OF THE WEST KUNLUN MOUNTAINS[J]. SEISMOLOGY AND GEOLOGY, 2025, 47(2): 405-428.

图/表 15

图 1 弯矩断层(a)和弯滑断层(b)形成的概念模型(引自Burbank et al., 2012)

Fig. 1 Bending-moment faults(a)and Flexural-slip faults(b)resulting from folding strata(Burbank et al., 2012).

图 2 固满背斜带的构造背景 a 西昆仑山前固满背斜带的几何展布, 白色虚线圈出了背斜带的轮廓, 地层产状引自文献(Li et al., 2016), 黄色箭头代表相对于欧亚大陆的GPS速度矢量(Wang et al., 2020), 底图为12.5m ALOS DEM栅影图, 插图指示了图a的位置; b 沿固满背斜带的三维地形剖面, 每个地形剖面位置见图a

Fig. 2 Geological setting of the Guman anticline belt.

图 3 固满背斜带中段弯矩正断层分布图 a 阔什塔格河和巴什兰干河之间的阶地划分、弯矩正断层分布图; b 弯矩正断层的卫星影像图, 红色箭头指示了弯矩正断层的位置, 蓝色箭头指示了阶地陡坎的位置, 影像图大体覆盖了整个图 4a的范围; c T3c阶地面上拍摄的弯矩正断层陡坎照片, 红色箭头指示了断层陡坎的位置, 照片中的摩托车为参照物, 照片位置见图b; d 皮西那河谷西岸低阶地面(T1b)跨坡向S的断层陡坎开挖的探槽, 揭示了陡倾的正断层, 探槽位置见图b; e 探槽南东壁断层面上可见清晰的垂直断层擦痕

Fig. 3 Bending-moment normal faults in the middle section of the Guman anticline.

图 4 研究区0.2m分辨率DEM数据, 展示了长地形剖面、跨断层陡坎地形剖面的位置 a 0.2m分辨率DEM渲染图, 展示了精细的地貌, RR'为T1和T3阶地面上沿断层距离起始位置的参考线(N27.9°E), 方向垂直于研究区陡坎的平均走向; 圆点标注了跨断层陡坎地形剖面的位置, 红、浅蓝、蓝色圆点分别代表了陡坎剖面完整性的好、中、差; 2条长粗蓝色实线为图 7沿阶地面提取长地形剖面的位置。b 无人机DEM数据与实测差分GPS数据的高程差剖面, 用于评估DEM数据的精度; 实测差分GPS测线为图a中的黑色实线; c 未解译的DEM渲染图, 红色箭头指示了弯矩正断层的位置,蓝色箭头指示了阶地陡坎的位置, 黑色圆点标注了所在处的阶地陡坎高度(除已注明处外, 高度误差通常约为10%)

Fig. 4 0.2m DEM data covering the study area shows location of long topographic and fault scarp profiles.

图 5 计算陡坎高度、最大坡度及连续剖面的方法 a 定义陡坎中下部处上、下地貌面的落差为陡坎的高度, 陡坎肩部和坡脚处上、下地貌面的落差作为陡坎高度的上、下限; b 在坡度剖面图上框选最大坡度及其附近的一些值, 取其平均值作为陡坎的最大坡度; c 沿断层某段内(窗口)的陡坎高度或最大坡度的概率密度分布, 红色、浅蓝色和蓝色分别代表了陡坎剖面完整性的好、中和差; d 叠加陡坎高度或最大坡度的概率密度分布可得到该段内(窗口)的累积概率密度分布图, 沿剖面以一定步长滑动窗口即可得到连续剖面。本示意图坐标轴数值已隐去, 保留单位仅用于展示物理量维度及比例关系

Fig. 5 Methods for calculating the scarp height, maximum slope, and continuous profile.

图 6 研究区阶地面、弯矩正断层解译图, 标注了陡坎高度和最大坡度

Fig. 6 Distribution of terraces and bending-moment normal faults in the study area (see labels for fault scarp heights and maximum slopes).

图 7 沿阶地面穿过整个弯矩正断层带的地形剖面, 展示了断层陡坎高度、围限地块的宽度和掀斜程度 a T3c阶地面上断层围限地块的宽度(L)、陡坎高度(V)和断层围限地块的坡度(S); b T1c阶地面上断层围限地块的宽度(L)、陡坎高度(V)和断层围限地块的坡度(S); c T3c和T1c阶地面上断层围限的每个地块净掀斜角度(扣除阶地面整体坡度后的剩余坡度), 剖面位置见图 4a; d 净掀斜角度-陡坎高度图。图中所列数值误差通常约为10%

Fig. 7 Long topographic profile along the terrace surfaces across the bending-moment normal fault belts, showing fault scarp height, width and tilt of fault-bounded blocks.

图 8 断层F1-2_T1c的位移和最大坡度剖面 a断层F1-2_T1c的地表迹线, 标注了沿断层的距离标尺(如1.0km)、阶地面划分(如T1c3)、断层分段(如Ⅰ)及断层陡坎的高度和最大坡度; b 断层F1-2_T1c的位移剖面, 标注了不同段的位移值; c 断层F1-2_T1c的陡坎最大坡度剖面, 标注了不同段的最大坡度值

Fig. 8 Profiles showing displacement and maximum slope of the Fault F1-2_T1c.

图 9 研究区主要弯矩正断层沿走向的位移剖面图

Fig. 9 Profiles showing displacement of the main bending-moment normal faults in the study area.

图 10 研究区主要弯矩正断层沿走向陡坎的最大坡度剖面图

Fig. 10 Maximum slope profiles of the main bending-moment normal faults in the study area.

图 11 累积位移剖面 a 每组断层的累积位移剖面; b 整条断层带的累积位移剖面

Fig. 11 Cumulative displacement profile.

表 1 研究区沿断层分段的陡坎高度和最大坡度值

Table1 The height and maximum slope of the scarp along the faults

断层	编号	高度 /m	最大坡度 /(°)	剖面个数	分段长度 /m	断层	编号	高度 /m	最大坡度 /(°)	剖面个数	分段长度 /m
F_1-1_T3c	1	14.4±1.9	26.7±4.6	9	1000	F_4-2_T1c	36	3.8±0.7	15.0±1.0	3	150
F_1-2_T1c	2	1.7±0.5	6.7±1.5	8	600		37	2.9±0.6	13.6+1.4/-4.1	8	550
	3	5.0±0.9	17.7±2.8	16	500		38	2.5±0.4	11.0+4.2/-1.5	4	300
	4	6.5±0.8	11.9±1.7	4	200	F_5-1_T3c	39	2.9±0.5	12.7±2.6	4	100
	5	4.2±0.9	12.0±2.0	13	700		40	4.5±0.8	15.9±2.0	6	300
	6	4.1±0.7	16.2±3.0	5	300	F_5-1_T1c	41	1.9±0.3	7.9±1.3	2	200
F_2-1_T3c	7	4.5±0.7	13.9±2.3	9	450		42	1.3±0.4	5.7±1.2	6	300
F_2-2_T3c	8	5.4±0.7	16.9±1.7	3	350		43	1.5±0.4	7.6±1.8	14	900
	9	8.3±0.5	14.4±1.6	2	200		44	1.7±0.9	8.4±1.6	13	350
F_2-2_T1c	10	6.0±1.0	23.7+2.6/-7.2	4	200		45	1.4±0.4	7.5±1.9	31	650
	11	5.1±1.1	19.7±2.4	12	700		46	2.2±0.5	8.9±1.3	15	400
	12	4.6+0.6/-1.3	19.1±2.3	4	400	F_5-2	47	0.7±0.3	4.6±0.8	18	400
	13	3.4±0.7	12.2±1.9	14	700	F_6-3	48	3.1±0.6	13.0±2.7	11	300
	14	2.3±0.6	9.9±1.5	12	600		49	5.7±0.8	12.8±1.8	4	200
F_2-3_T1c	15	2.7±0.5	10.0±1.6	10	800		50	3.8±0.8	14.3±1.9	14	700
	16	2.3±0.4	9.6±1.3	8	600	F_6-2	51	3.1±0.8	10.7±2.5	13	400
F_3-1_T3c	17	10.6±1.5	25.9±3.6	8	650		52	4.4±1.3	13.2±2.5	13	500
	18	8.2±1.1	20.3±5.5	9	450		53	1.5+1.2/-0.3	9.0+2.0/-1.8	14	500
F_3-2_T3c	19	1.4±0.6	5.7±1.6	3	200	F_6-1	55	5.9±0.8	22.4±2.4	2	200
	20	4.9±1.1	21.2±5.0	6	250		56	4.3±0.8	18.2±3.2	9	500
F_3-2_T1c	21	2.6±0.5	13.1±1.7	2	150		57	5.6±0.8	15.4±2.2	11	700
	22	2.1+0.7/-0.3	9.0±1.4	7	500		58	3.8±0.8	14.3±1.9	14	800
	23	1.6±0.4	6.3+2.9/-1.2	9	500	F_7-6	59	0.5±0.3	3.3±0.8	15	500
	24	3.1±0.6	12.1±1.7	4	200	F_7-5	60	1.0±0.4	5.2±0.9	26	950
F_4-1_T3c	25	1.6±0.6	8.7+3.1/-1.7	5	200		61	0.7±0.2	5.7±1.0	12	350
	26	3.1±0.7	12.3±2.2	6	200	F_7-4	62	1.6±0.5	7.6±1.3	33	1100
	27	3.7±0.6	15.0±2.2	14	550		63	0.6±0.2	4.6±0.8	4	200
	28	5.4±1.0	17.7±2.2	10	650	F_7-3	64	1.3±0.5	6.5±1.4	38	1000
	29	2.6±0.6	13.9±1.5	4	100	F_7-2	65	1.7±0.6	7.2±1.3	30	900
	30	1.1±0.3	5.4±1.8	11	300	F_7-1	66	1.3±0.4	7.0±1.3	20	600
	31	1.3±0.3	7.7±1.1	13	250	F_8-1_T3c	67	10.6±1.9	19.1±2.9	18	600
F_4-2_T1c	32	2.0±0.4	8.5±0.9	2	100		68	8.2±1.3	19.3±3.0	6	200
	33	2.0±0.6	7.2±1.3	7	450		69	3.6±0.6	10.0±1.4	9	200
	34	1.0±0.3	5.5±0.8	4	150	F_8-2_T1c	70	1.7±0.4	4.6+2.6/-0.9	25	680
	35	1.2±0.2	4.9±1.2	6	250	F_8-2_T1b	71	1.0±0.3	5.3±0.8	11	620

表 1 研究区沿断层分段的陡坎高度和最大坡度值

Table1 The height and maximum slope of the scarp along the faults

断层	编号	高度 /m	最大坡度 /(°)	剖面个数	分段长度 /m	断层	编号	高度 /m	最大坡度 /(°)	剖面个数	分段长度 /m
F_1-1_T3c	1	14.4±1.9	26.7±4.6	9	1000	F_4-2_T1c	36	3.8±0.7	15.0±1.0	3	150
F_1-2_T1c	2	1.7±0.5	6.7±1.5	8	600		37	2.9±0.6	13.6+1.4/-4.1	8	550
	3	5.0±0.9	17.7±2.8	16	500		38	2.5±0.4	11.0+4.2/-1.5	4	300
	4	6.5±0.8	11.9±1.7	4	200	F_5-1_T3c	39	2.9±0.5	12.7±2.6	4	100
	5	4.2±0.9	12.0±2.0	13	700		40	4.5±0.8	15.9±2.0	6	300
	6	4.1±0.7	16.2±3.0	5	300	F_5-1_T1c	41	1.9±0.3	7.9±1.3	2	200
F_2-1_T3c	7	4.5±0.7	13.9±2.3	9	450		42	1.3±0.4	5.7±1.2	6	300
F_2-2_T3c	8	5.4±0.7	16.9±1.7	3	350		43	1.5±0.4	7.6±1.8	14	900
	9	8.3±0.5	14.4±1.6	2	200		44	1.7±0.9	8.4±1.6	13	350
F_2-2_T1c	10	6.0±1.0	23.7+2.6/-7.2	4	200		45	1.4±0.4	7.5±1.9	31	650
	11	5.1±1.1	19.7±2.4	12	700		46	2.2±0.5	8.9±1.3	15	400
	12	4.6+0.6/-1.3	19.1±2.3	4	400	F_5-2	47	0.7±0.3	4.6±0.8	18	400
	13	3.4±0.7	12.2±1.9	14	700	F_6-3	48	3.1±0.6	13.0±2.7	11	300
	14	2.3±0.6	9.9±1.5	12	600		49	5.7±0.8	12.8±1.8	4	200
F_2-3_T1c	15	2.7±0.5	10.0±1.6	10	800		50	3.8±0.8	14.3±1.9	14	700
	16	2.3±0.4	9.6±1.3	8	600	F_6-2	51	3.1±0.8	10.7±2.5	13	400
F_3-1_T3c	17	10.6±1.5	25.9±3.6	8	650		52	4.4±1.3	13.2±2.5	13	500
	18	8.2±1.1	20.3±5.5	9	450		53	1.5+1.2/-0.3	9.0+2.0/-1.8	14	500
F_3-2_T3c	19	1.4±0.6	5.7±1.6	3	200	F_6-1	55	5.9±0.8	22.4±2.4	2	200
	20	4.9±1.1	21.2±5.0	6	250		56	4.3±0.8	18.2±3.2	9	500
F_3-2_T1c	21	2.6±0.5	13.1±1.7	2	150		57	5.6±0.8	15.4±2.2	11	700
	22	2.1+0.7/-0.3	9.0±1.4	7	500		58	3.8±0.8	14.3±1.9	14	800
	23	1.6±0.4	6.3+2.9/-1.2	9	500	F_7-6	59	0.5±0.3	3.3±0.8	15	500
	24	3.1±0.6	12.1±1.7	4	200	F_7-5	60	1.0±0.4	5.2±0.9	26	950
F_4-1_T3c	25	1.6±0.6	8.7+3.1/-1.7	5	200		61	0.7±0.2	5.7±1.0	12	350
	26	3.1±0.7	12.3±2.2	6	200	F_7-4	62	1.6±0.5	7.6±1.3	33	1100
	27	3.7±0.6	15.0±2.2	14	550		63	0.6±0.2	4.6±0.8	4	200
	28	5.4±1.0	17.7±2.2	10	650	F_7-3	64	1.3±0.5	6.5±1.4	38	1000
	29	2.6±0.6	13.9±1.5	4	100	F_7-2	65	1.7±0.6	7.2±1.3	30	900
	30	1.1±0.3	5.4±1.8	11	300	F_7-1	66	1.3±0.4	7.0±1.3	20	600
	31	1.3±0.3	7.7±1.1	13	250	F_8-1_T3c	67	10.6±1.9	19.1±2.9	18	600
F_4-2_T1c	32	2.0±0.4	8.5±0.9	2	100		68	8.2±1.3	19.3±3.0	6	200
	33	2.0±0.6	7.2±1.3	7	450		69	3.6±0.6	10.0±1.4	9	200
	34	1.0±0.3	5.5±0.8	4	150	F_8-2_T1c	70	1.7±0.4	4.6+2.6/-0.9	25	680
	35	1.2±0.2	4.9±1.2	6	250	F_8-2_T1b	71	1.0±0.3	5.3±0.8	11	620

图 12 固满背斜地下几何结构与阶地剖面对比图 a 阶地剖面垂直放大了30倍, 弯矩正断层发育在固满背斜带的北部、地形台阶的肩部。地形剖面P的位置见图 3a; b 地震反射剖面解释引自文献(Li et al., 2016; Lu et al., 2016), 揭示下伏盲逆断层具有下断坪-断坡-上断坪的几何结构, 背形断弯的位置对应了地表的弯矩正断层带, 蓝色箭头指示的河谷变窄也在此处, 说明该轴域是活动的。地震反射剖面的位置见图3a中红色直线SS'。右上角的插图解释了弯矩正断层的成因

Fig. 12 Comparison of underground structure from seismic reflection profile and surface terraces of Guman anticline.

图 13 等间距弯矩正断层形成的机制 a 地层弯曲下的应变状态及应变与地层弯曲程度和半径之间的关系(引自Ramsay et al., 1987); b 拉张作用下, 区域应力等于正应力 σ n = σ r n, 破裂存在会引起局部应力下降, 阻止破裂在强度阴影区形成(强度S), 这样一个效应使得变形区逐步形成等间距(S)的破裂面(引自Zuza et al., 2017)

Fig. 13 Generation mechanism of evenly-spaced bending-moment normal faults.

图 14 弯矩正断层围限的地堑面积(A)与地层弯曲程度(α)、断层延伸的深度(r)之间的关系图(引自Livio et al., 2014, 2019)

Fig. 14 Relationship among fault-bounded graben area(A), bedding curvature(α), and fault depth(r)(Livio et al., 2014, 2019).

参考文献 56

[1]	程晓敢, 黄智斌, 陈汉林, 等. 2012. 西昆仑山前冲断带断裂特征及构造单元划分[J]. 岩石学报, 28(8): 2591-2601.
	CHENG Xiao-gan, HUANG Zhi-bin, CHEN Han-lin, et al. 2012. Fault characteristics and division of tectonic units of the thrust belt in the front of the West Kunlun Mountains[J]. Acta Petrologica Sinica, 28(8): 2591-2601. (in Chinese)
[2]	邓洪菱, 张长厚, 李海龙, 等. 2009. 褶皱相关断裂构造及其地质意义[J]. 自然科学进展, 19(3): 285-296.
	DENG Hong-ling, ZHANG Chang-hou, LI Hai-long, et al. 2009. Fold-related fault structure and its geological significance[J]. Progress in Natural Science, 19(3): 285-296. (in Chinese)
[3]	高锐, 黄东定, 卢德源, 等. 2000. 横过西昆仑造山带与塔里木盆地结合带的深地震反射剖面[J]. 科学通报, 45(17): 1874-1879.
	GAO Rui, HUANG Dong-ding, LU De-yuan, et al. 2000. Deep seismic reflection profile across the West Kunlun orogenic belt and Tarim Basin[J]. Chinese Science Bulletin, 45(17): 1874-1879. (in Chinese)
[4]	李安, 杨晓平, 黄伟亮, 等. 2011. 焉耆盆地北缘哈尔莫敦背斜区的活动断裂及其形成机制[J]. 地震地质, 33(4): 789-803. doi: 10.3969/j.issn.0253-4967.2011.04.005.
	LI An, YANG Xiao-ping, HUANG Wei-liang, et al. 2011. Active faults of the Haermodun anticline and their formation mechanism in the north margin of the Yanqi Basin[J]. Seismology and Geology, 33(4): 789-803. (in Chinese) DOI
[5]	梁瀚, 汪新, 陈伟, 等. 2014. 西昆仑山前和田-柯克亚挤压构造带新生代变形时序及其地质意义[J]. 大地构造与成矿学, 38(1): 27-37.
	LIANG Han, WANG Xin, CHEN Wei, et al. 2014. Cenozoic deformation sequence of Hetian-Kekeya structural belt in the piedmont of West Kunlun Mountains[J]. Geotectonica et Metallogenia, 38(1): 27-37. (in Chinese)
[6]	潘家伟, 李海兵, 孙知明, 等. 2010. 塔里木盆地中南部麻扎塔格逆冲--褶皱带变形特征及其意义[J]. 地质科学, 45(4): 1038-1056.
	PAN Jia-wei, LI Hai-bing, SUN Zhi-ming, et al. 2010. Deformation features of the Mazartagh fold-thrust belt, south central Tarim Basin and its tectonic significances[J]. Chinese Journal of Geology, 45(4): 1038-1056. (in Chinese)
[7]	潘家伟, 李海兵, van der Woerd J, 等. 2007. 西昆仑山前冲断带晚新生代构造地貌特征[J]. 地质通报, 26(10): 1368-1379.
	PAN Jia-wei, LI Hai-bing, van der Woerd J, et al. 2007. Late Cenozoic morphotectonic features of the thrust belt in the front of the West Kunlun Mountains[J]. Geological Bulletin of China, 26(10): 1368-1379. (in Chinese)
[8]	司家亮, 李海兵, 裴军令, 等. 2011. 塔里木盆地玛扎塔格第四纪沉积环境演变及构造学意义[J]. 岩石学报, 27(1): 321-332.
	SI Jia-liang, LI Hai-bing, PEI Jun-ling, et al. 2011. Sedimentary environment variation and its tectonic significance of Mazar Tagh in the middle Tarim Basin[J]. Acta Petrologica Sinica, 27(1): 321-332. (in Chinese)
[9]	肖安成, 杨树锋, 陈汉林, 等. 2000. 西昆仑山前冲断系的结构特征[J]. 地学前缘, 7(S1): 128-136.
	XIAO An-cheng, YANG Shu-feng, CHEN Han-lin, et al. 2000. Structural characteristics of thrust system in the front of the west Kunlun mountains[J]. Earth Science Frontiers, 7(S1): 128-136. (in Chinese)
[10]	杨海军, 李曰俊, 冯晓军, 等. 2007. 塔里木盆地玛扎塔格构造带断裂构造分析[J]. 地质科学, 42(3): 506-517.
	YANG Hai-jun, LI Yue-jun, FENG Xiao-jun, et al. 2007. Analysis on thrustings of the Mazhatage structural belt in the Tarim Basin[J]. Chinese Journal of Geology, 42(3): 506-517. (in Chinese)
[11]	周新源, 罗金海, 王清华. 2004. 塔里木盆地南缘冲断带构造特征及其油气地质特征[J]. 中国科学(D辑), 34(S1): 56-62.
	ZHOU Xin-yuan, LUO Jin-hai, WANG Qing-hua. 2004. Structural characteristics and oil-gas geologicalcharacteristics of thrust belt in the southern margin of Tarim Basin[J]. Science in China(Ser D), 34(S1): 56-62. (in Chinese)
[12]	Avouac J P, Peltzer G. 1993. Active tectonics in southern Xinjiang, China: Analysis of terrace riser and normal fault scarp degradation along the Hotan-Qira fault system[J]. Journal of Geophysical Research, 98(B12): 21773-21807. doi: 10.1029/93JB02172.
[13]	Baby G, Simoes M, Barrier L, et al. 2022. Kinematics of Cenozoic shortening of the Hotan anticline along the northwestern margin of the Tibetan plateau(Western Kunlun, China)[J]. 41(5): e2021TC006928. doi: 10.1029/2021TC006928.
[14]	Berberian M. 1979. Earthquake faulting and bedding thrust associated with the Tabas-e-Golshan(Iran)earthquake of September 16, 1978[J]. Bulletin of the Seismological Society of America, 69(6): 1861-1887.
[15]	Berberian M. 2014. Coseismic, blind, reverse-fault-related, flexural-slip folding and faulting at the surface[G]// Berberian M(Eds). Developments in Earth Surface Processes. Elsevier, Amsterdam: 421-437. doi: 10.1016/B978-0-444-63292-0.00015-6.
[16]	Burbank D W, Anderson R S. 2012. Tectonic Geomorphology[M]. Blackwell Publishing, West Sussex, UK.
[17]	Cao K, Wang G C, Bernet M, et al. 2015. Exhumation history of the West Kunlun Mountains, northwestern Tibet: Evidence for a long-lived, rejuvenated orogen[J]. Earth and Planetary Science Letters, 432:391-403. doi: 10.1016/j.epsl.2015.10.033.
[18]	Caskey S J. 1995. Geometric relations of dip slip to a faulted ground surface: New nomograms for estimating components of fault displacement[J]. Journal of Structural Geology, 17(8): 1197-1202. doi: 10.1016/0191-8141(95)00023-7.
[19]	Chen H, Zhang Y, Cheng X, et al. 2022. Using migrating growth strata to confirm a -230-km-long detachment thrust in the southern Tarim Basin[J]. Journal of Structural Geology, 154:104488. doi: 10.1016/j.jsg.2021.104488.
[20]	Cheng X, Chen H, Lin X, et al. 2017. Geometry and kinematic evolution of the Hotan-Tiklik segment of the Western Kunlun thrust belt: Constrained by structural analyses and apatite fission track thermochronology[J]. The Journal of Geology, 125(1): 65-82. doi: 10.1086/689187.
[21]	Duffy O B, Bell R E, Jackson C A L, et al. 2015. Fault growth and interactions in a multiphase rift fault network: Horda Platform, Norwegian North Sea[J]. Journal of Structural Geology, 80:99-119. doi: 10.1016/j.jsg.2015.08.015.
[22]	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: 10.1130/ges02096.1.
[23]	Guilbaud C, Simoes M, Barrier L, et al. 2017. Kinematics of active deformation across the Western Kunlun mountain range(Xinjiang, China)and potential seismic hazards within the southern Tarim Basin[J]. Journal of Geophysical Research: Solid Earth, 122(12): 10398-10426. doi: 10.1002/2017jb014069.
[24]	Gutiérrez F, Carbonel D, Kirkham R M, et al. 2014. Can flexural-slip faults related to evaporite dissolution generate hazardous earthquakes?The case of the Grand Hogback monocline of west-central Colorado[J]. Geological Society of America Bulletin, 126(11-12): 1481-1494. doi: 10.1130/b31054.1.
[25]	Hanks T C. 2000. The age of scarplike landforms from diffusion-equation analysis[G]// Noller J S, Sowers J M, Lettis W R(Eds). Quaternary Geochronology: Methods and applications. American Geophysical Union, Washington, DC: 313-338.
[26]	Harwin S, Lucieer A. 2012. Assessing the accuracy of georeferenced point clouds produced via multi-view stereopsis from Unmanned Aerial Vehicle(UAV)imagery[J]. Remote Sensing, 4(6): 1573-1599. doi: 10.3390/rs4061573.
[27]	He P, Wang Q, Ding K, et al. 2016. Source model of the 2015 M_W6.4 Pishan earthquake constrained by interferometric synthetic aperture radar and GPS: Insight into blind rupture in the western Kunlun Shan[J]. Geophysical Research Letters, 43(4): 1511-1519. doi: 10.1002/2015gl067140.
[28]	Hu Y. 2003. Automated extraction of digital terrain models, roads and buildings using airborne LiDAR data[D]. University of Calgary, Department of Geomatics Engineering, Canada.
[29]	James M R, Robson S. 2012. Straightforward reconstruction of 3D surfaces and topography with a camera: Accuracy and geoscience application[J]. Journal of Geophysical Research: Earth Surface, 117(F3): F03017. doi: 10.1029/2011jf002289.
[30]	Jiang X D, Li Z X. 2014. Seismic reflection data support episodic and simultaneous growth of the Tibetan plateau since 25 Myr[J]. Nature Communications, 5:5453. doi: 10.1038/ncomms6453.
[31]	Kelsey H M, Sherrod B L, Nelson A R, et al. 2008. Earthquakes generated from bedding plane-parallel reverse faults above an active wedge thrust, Seattle fault zone[J]. Geological Society of America Bulletin, 120(11-12): 1581-1597. doi: 10.1130/B26282.1.
[32]	Laborde A, Barrier L, Simoes M, et al. 2019. Cenozoic deformation of the Tarim Basin and surrounding ranges(Xinjiang, China): A regional overview[J]. Earth-Science Reviews, 197:102891. doi: 10.1016/j.earscirev.2019.102891.
[33]	Langridge R M, Ries W F, Farrier T, et al. 2014. Developing sub 5-m LiDAR DEMs for forested sections of the Alpine and Hope faults, South Island, New Zealand: Implications for structural interpretations[J]. Journal of Structural Geology, 64:53-66. doi: 10.1016/j.jsg.2013.11.007.
[34]	Li H, Chevalier M L, Tapponnier P, et al. 2021. Block tectonics across western Tibet and multi-millennial recurrence of great earthquakes on the Karakax fault[J]. Journal of Geophysical Research: SolidEarth, 126(12): e2021JB022033. doi: 10.1029/2021JB022033.
[35]	Li T, Chen J, Fang L, et al. 2016. The 2015 M_W6.4 Pishan earthquake: Seismic hazards of an active blind wedge thrust system at the western Kunlun range front, northwest Tibetan plateau[J]. Seismological Research Letters, 87(3): 601-608. doi: 10.1785/0220150205.
[36]	Li T, Chen J, Thompson J A, et al. 2015. Active flexural-slip faulting: A study from the Pamir-Tian Shan convergent zone, NW China[J]. Journal of Geophysical Research: Solid Earth, 120(6): 4359-4378. doi: 10.1002/2014JB011632.
[37]	Li T, Chen J, Thompson Jobe J A, et al. 2018. Active bending-moment faulting: Geomorphic expression, controlling conditions, accommodation of fold deformation[J]. Tectonics, 37(8): 2278-2306. doi: 10.1029/2018tc004982.
[38]	Livio F A, Berlusconi A, Zerboni A, et al. 2014. Progressive offset and surface deformation along a seismogenic blind thrust in the Po Plain foredeep(Southern Alps, Northern Italy)[J]. Journal of Geophysical Research: Solid Earth, 119(10): 7701-7721. doi: 10.1002/2014jb011112.
[39]	Livio F, Kettermann M, Reicherter K, et al. 2019. Growth of bending-moment faults due to progressive folding: Insights from sandbox models and paleoseismological implications[J]. Geomorphology, 326:152-166. doi: 10.1016/j.geomorph.2018.02.012.
[40]	Lu R, Xu X, He D, et al. 2016. Coseismic and blind fault of the 2015 Pishan M_W6.5 earthquake: Implications for the sedimentary-tectonic framework of the western Kunlun Mountains, northern Tibetan plateau[J]. Tectonics, 35(4): 956-964. doi: 10.1002/2015tc004053.
[41]	McCalpin J P. 2009. Paleoseismology(Second Edition)[M]. Academic Press, San Diego.
[42]	Mitra S. 2002. Fold-Accommodation Faults[J]. AAPG Bulletin, 86(4): 671-693. doi: 10.1306/61eedb7a-173e-11d7-8645000102c1865d.
[43]	Philip H, Meghraoui M. 1983. Structural analysis and interpretation of the EI Asnam earthquake of October 10, 1980[J]. Tectonics, 2(1): 17-49.
[44]	Ramsay J G, Huber M I. 1987. Folds and fractures[G]// Ramsay J G, Huber M I(Eds). The Techniques of Modern Structural Geology(Volume 2). Academic Press, London. doi: 10.1016/0191-8141(88)90041-7.
[45]	Reitman N G, Bennett S E K, Gold R D, et al. 2015. High-resolution trench photomosaics from image-based modeling: Workflow and error analysis[J]. Bulletin of the Seismological Society of America, 105(5): 2354-2366. doi: 10.1785/0120150041.
[46]	Rockwell T K, Ragona D E, Meigs A J, et al. 2014. Inferring a thrust-related earthquake history from secondary faulting: A long rupture record of La Laja Fault, San Juan, Argentina[J]. Bulletin of the Seismological Society of America, 104(1): 269-284. doi: 10.1785/0120110080.
[47]	Sobel E R, Schoenbohm L M, Chen J, et al. 2011. Late Miocene-Pliocene deceleration of dextral slip between Pamir and Tarim: Implications for Pamir orogenesis[J]. Earth and Planetary Science Letters, 304(3-4): 369-378. doi: 10.1016/j.epsl.2011.02.012.
[48]	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: Solid Earth, 125(2): e2019JB018774. doi: 10.1029/2019jb018774.
[49]	Xu J, Chen J, Li T, et al. 2024. ²¹Ne and ¹⁰Be dating of folded fluvial terraces: Constraining active deformation of the Guman fold along the foothill of the western Kunlun mountains(Xinjiang, China)[J]. Journal of Structural Geology, 187:105244. doi: 10.1016/j.jsg.2024.105244.
[50]	Yeats R S, Sieh K, Allen C R. 1997. The Geology of Earthquakes[M]. Oxford University Press, Oxford.
[51]	Yin A, Rumelhart P E, Butler R, et al. 2002. Tectonic history of the Altyn Tagh fault system in northern Tibet inferred from Cenozoic sedimentation[J]. Geological Society of America Bulletin, 114(10): 1257-1295. doi: 10.1130/0016-7606(2002)114＜1257:THOTAT＞2.0.CO;2.
[52]	Yin A, Zuza A V, Pappalardo R T. 2016. Mechanics of evenly spaced strike-slip faults and its implications for the formation of tiger-stripe fractures on Saturn’s moon Enceladus[J]. Icarus, 266:204-216. doi: 10.1016/j.icarus.2015.10.027.
[53]	Zhang Y, Chen H, Shi X, et al. 2023. Reconciling patterns of long-term topographic growth with coseismic uplift by synchronous duplex thrusting[J]. Nature Communications, 14(1): 8073. doi: 10.1038/s41467-023-43994-6. PMID
[54]	Zielke O, Arrowsmith J R, Grant Ludwig L, et al. 2012. High-resolution topography-derived offsets along the 1857 Fort Tejon earthquake rupture trace, San Andreas Fault[J]. Bulletin of the Seismological Society of America, 102(3): 1135-1154. doi: 10.1785/0120110230.
[55]	Zielke O, Klinger Y, Arrowsmith J R. 2015. Fault slip and earthquake recurrence along strike-slip faults: Contributions of high-resolution geomorphic data[J]. Tectonophysics, 638:43-62. doi: 10.1016/j.tecto.2014.11.004.
[56]	Zuza A V, Yin A, Lin J, et al. 2017. Spacing and strength of active continental strike-slip faults[J]. Earth and Planetary Science Letters, 457:49-62. doi: 10.1016/j.epsl.2016.09.041.

西昆仑山前固满背斜带弯矩正断层活动特征及其形成机制

DENSE BENDING MOMENT NORMAL FAULT SCARPS ALONG THE GUMAN ANTICLINE AT THE FOOTHILL OF THE WEST KUNLUN MOUNTAINS

RichHTML

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

图/表 15

参考文献 56

相关文章 15

编辑推荐

Metrics

本文评价

[1]	许建红, 陈杰, 魏占玉, 李涛. 基于扩散方程的陡坎形貌测年方法进展[J]. 地震地质, 2023, 45(4): 811-832.
[2]	郑海刚, 姚大全, 赵朋, 杨源源, 黄金水. 郯庐断裂带赤山段全新世新活动的特征[J]. 地震地质, 2023, 45(1): 127-138.
[3]	李安, 万波, 王晓先, 计昊旻, 索锐. 金州断裂盖州北鞍山段古地震破裂的新证据[J]. 地震地质, 2023, 45(1): 111-126.
[4]	黄帅堂, 常想德, 马建, 胡伟华, 任静, 刘建明, 张文秀, 赖爱京. 天山北麓库松木契克山山前断裂东段断层陡坎研究[J]. 地震地质, 2022, 44(1): 20-34.
[5]	苗树清, 胡宗凯, 张玲, 杨海波, 杨晓平. 洪积扇顶部活动走滑断裂的断错地貌分析——以新疆塔城盆地东缘阿合别斗河冲洪积扇为例[J]. 地震地质, 2021, 43(3): 488-503.
[6]	雷惊昊, 李有利, 胡秀, 辛伟林, 熊建国, 钟岳志. 东大河阶地陡坎对民乐-大马营断裂垂直滑动速率的指示[J]. 地震地质, 2017, 39(6): 1256-1266.
[7]	张玲, 杨晓平, 黄伟亮, 李胜强. 褶皱陡坎中相关断层在缩短量计算中的作用——以东秋里塔格背斜为例[J]. 地震地质, 2015, 37(3): 697-708.
[8]	杨晓东, 陈杰, 李涛, 李文巧, 刘浪涛, 杨会丽. 塔里木西缘明尧勒背斜的弯滑褶皱作用与活动弯滑断层陡坎[J]. 地震地质, 2014, 36(1): 14-27.
[9]	肖伟鹏, 陈杰, 李涛, 李文巧, Thompson J. 帕米尔北缘木什背斜第四纪滑脱褶皱作用与北翼逆断裂的生长[J]. 地震地质, 2011, 33(2): 289-307.
[10]	闵伟, 焦德成, 周本刚, 盛俭, 陈涛. 依兰-伊通断裂全新世活动的新发现及其意义[J]. 地震地质, 2011, 33(1): 141-150.
[11]	程建武, 冉勇康, 杨晓平, 徐锡伟. 西南天山柯坪塔格前缘断裂带东段晚第四纪活动特征[J]. 地震地质, 2006, 28(2): 258-268.
[12]	郑荣章, 徐锡伟, 王峰, 李建平, 计凤桔. 阿尔金构造系晚更新世中晚期以来的逆冲活动[J]. 地震地质, 2005, 27(3): 361-373.
[13]	江娃利. 北京平谷地区地表陡坎的成因识别[J]. 地震地质, 1999, 21(4): 309-315.
[14]	中屠炳明, 宋方敏, 曹忠权, 汪一鹏. 秦岭北麓晚第四纪断层陡坎的初步研究[J]. 地震地质, 1991, 13(1): 15-25.
[15]	虢顺民, 廖玉华, 李玉龙. 美国爱达荷州中部洛斯特河断层麦凯段晚第四纪断层陡坎与地震[J]. 地震地质, 1987, 9(3): 61-70.