西南天山喀什背斜东倾伏端的生长演化和地貌响应: 基于地质地貌、 地震反射剖面和磁性地层数据的综合分析

doi:10.3969/j.issn.0253-4967.2025.02.20240157

地震地质 ›› 2025, Vol. 47 ›› Issue (2): 369-383.DOI: 10.3969/j.issn.0253-4967.2025.02.20240157

西南天山喀什背斜东倾伏端的生长演化和地貌响应: 基于地质地貌、地震反射剖面和磁性地层数据的综合分析

何鹏宇¹⁾(), 李涛¹⁾^,^*(), 陈竹新²⁾, 陈杰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⁾ 中国石油勘探开发研究院, 北京 100083

收稿日期:2024-12-16 修回日期:2025-02-10 出版日期:2025-04-20 发布日期:2025-06-07
通讯作者: * 李涛, 男, 1985年生, 研究员, 博士生导师, 主要研究方向为活动构造, E-mail: litao.410@163.com。
作者简介:
何鹏宇, 男, 1995年生, 现为中国地震局地质研究所构造地质学在读博士研究生, 主要从事新构造、活动构造等方面的研究, E-mail: pengyuhe2019@163.com。
基金资助:
国家重点研发计划项目(2022YFC3003700); 中国石油重大科技专项(2023ZZ0202); 新疆维吾尔自治区重点研发项目(2022B03001-1)

GROWING HISTORY AND GEOMORPHIC RESPONSE OF THE EASTERN TERMINATION OF KASHI ANTICLINE, SOUTHWESTERN TIAN SHAN: AN INTEGRATED ANALYSIS OF GEOLOGY, GEOMORPHOLOGY, SEISMIC REFLECTION PROFILE AND MAGNETOSTRATIGRAPHY

HE Peng-yu¹⁾(), LI Tao¹⁾^,^*(), CHEN Zhu-xin²⁾, CHEN Jie¹⁾

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⁾ Research Institute of Petroleum Exploration and Development, Beijing 100083, China

Received:2024-12-16 Revised:2025-02-10 Online:2025-04-20 Published:2025-06-07

摘要/Abstract

摘要：

喀什背斜位于西南天山喀什前陆冲断带的前缘, 以北与阿图什背斜相望, 向西和明尧勒背斜相接。前人对该背斜的研究主要集中在地表出露部分, 而对隐伏于地下的倾伏端研究较少。文中利用深度-隆升面积法对横切背斜东倾伏端的地震剖面进行了分析, 获得以下几方面认识: 1)背斜东倾伏端的生长受距地表约6.8km的古近系滑脱层控制。2)沿地震剖面, 背斜总缩短量为(882±79)m, 生长过程中有面积约3.4km²的物质流入剖面。3)通过对生长地层的分析和已有的磁性地层学结果, 估算剖面处背斜生长起始时间约为距今2.1Ma, 缩短速率恒定约为0.4mm/a; 由于背斜东倾伏端在距今约2.1Ma开始生长, 因此整个背斜开始生长的时间早于距今2.1Ma。4)剖面处背斜隆升速率可能大致恒定在约0.4mm/a, 也可能在距今约1.6Ma时由之前的约0.1mm/a增大至之后的约0.4mm/a; 由于隆升速率一直小于沉积速率, 背斜并未在地表形成地形起伏。文中研究表明, 对隐伏地下的背斜倾伏端的解析可对滑脱层位置、缩短和隆升历史、生长起始时间及生长过程中是否有盈余面积加入等进行准确限定, 以此可对整个背斜的生长演化进行更为完整可靠的约束。

关键词: 天山, 喀什背斜, 倾伏端, 生长地层, 滑脱褶皱, 深度-隆升面积法

Abstract:

The Kashi anticline, located along the leading edge of the Kashi foreland thrust system in the southwestern Tian Shan of China, confronts the Atushi Anticline to the north and connects with the Mingyaole Anticline to the west. The Kashi anticline manifests at the surface as an elongated hillock with a nearly EW strike. The morphology of the anticline is roughly box-shaped, with the southern limb being gentler compared to the northern limb. As a significant component of the Tianshan orogenic belt’s frontal zone, the study of the tectonic evolution of the Kashi Anticline is crucial for understanding the Cenozoic tectonic deformation and crustal shortening processes of the Tian Shan. Previous studies on this fold are primarily focused on its surface-expression part, with little or no focus on its lateral termination that is not expressed on the land surface, which has limited the comprehensive understanding of the anticline’s overall evolutionary process. The study employs the depth-relief area method, combined with high-resolution seismic reflection profile data, to conduct a detailed structural analysis of the eastern termination of the Kashi anticline.
Through meticulous interpretation and quantitative analysis of the seismic profiles, the following key insights have been obtained: Firstly, along the seismic profile, the Cenozoic strata are approximately 6.8km thick, while the Mesozoic-Paleozoic strata are about 2.2km thick. The eastern termination of the anticline detaches along the Paleogene unit, with a depth of ~6.8km. This detachment layer governs the deformation patterns and magnitudes of the overlying strata. Secondly, along the seismic profile, the total shortening of the anticline is estimated to be(882±79)m, of which approximately 94% is attributed to shear shortening, and about 6% is due to curvietric shortening. During the folding process, materials with an excess area of ~3.4km² enter the cross section. Thirdly, according to the analysis of growth strata and published magnetostratigraphic data, the folding of the eastern termination initiates at the age of ~2.1Ma, which implies that the initiation age of the fold should be much older than 2.1Ma. The shortening rate remains at an approximate constant of ~0.4mm/a since the folding initiation. Fourthly, for the pre-growth strata, the uplift of the anticline gradually increases upward with depth, reaching a maximum of approximately 770m at the top boundary of the pre-growth strata. Analysis of the growth strata indicates that the uplift rate either keeps a constant of ~0.4mm/a, or increases significantly from an earlier rate of ~0.1mm/a to a later rate of 0.4 mm/a at the age point of ~1.6Ma. Notably, because the uplift rate is smaller than the sediment rate, the fold exhibits no expression on the surface of the anticline.
Our study exemplifies that an analysis of the buried lateral termination of a fold can well determine the detachment level, shortening and uplift histories, initiation age of the fold, as well as whether or not the excess area enters the cross section during the folding process. These constraints provide a completer and more reliable basis for understanding the entire growing history of the fold. Furthermore, the results demonstrate that the analysis of buried structures in the frontal zones of orogenic belts is indispensable for a comprehensive understanding of regional tectonic deformation characteristics and evolutionary history.

Key words: Tian Shan, Kashi anticline, fold’s lateral termination, growth strata, detachment fold, depth-relief area method

何鹏宇, 李涛, 陈竹新, 陈杰. 西南天山喀什背斜东倾伏端的生长演化和地貌响应: 基于地质地貌、地震反射剖面和磁性地层数据的综合分析[J]. 地震地质, 2025, 47(2): 369-383.

HE Peng-yu, LI Tao, CHEN Zhu-xin, CHEN Jie. GROWING HISTORY AND GEOMORPHIC RESPONSE OF THE EASTERN TERMINATION OF KASHI ANTICLINE, SOUTHWESTERN TIAN SHAN: AN INTEGRATED ANALYSIS OF GEOLOGY, GEOMORPHOLOGY, SEISMIC REFLECTION PROFILE AND MAGNETOSTRATIGRAPHY[J]. SEISMOLOGY AND GEOLOGY, 2025, 47(2): 369-383.

图/表 8

图 1 构造隆升-沉积作用对褶皱地貌的控制(据Daëron等(2007)修改) a 若沉积速率>隆升速率, 褶皱变形未引起地形起伏; b 若沉积速率<隆升速率, 褶皱变形形成地形起伏

Fig. 1 The control of uplift-deposition interaction on the folding surface expression (adapted from Daëron et al., 2007).

图 2 喀什背斜地形、地质和地貌特征 a 喀什背斜区域地质背景; Bai 伯什克然木河; Bo 博古孜河; Ka 喀浪勾律克河; Ke 克孜勒苏河。b 喀什背斜ASTER影像、地质简图和古地磁剖面位置。c 喀什背斜地形纵剖面, 由背斜轴两侧各5km宽的范围内极大值、平均值和极小值获得, 地形数据据ASTER卫星30m分辨率的DEM。d 喀什背斜构造横剖面, 据文献(Chen et al., 2007)修改。剖面位置见图 2b

Fig. 2 Topography, geology and geomorphology of the Kashi anticline.

图 3 喀什背斜喀什西剖面和喀什城剖面磁性地层数据(剖面位置见图2b) 喀什西和喀什城剖面(Chen et al., 2007)均采自阿图什组上段和西域组下段, 厚度分别约为1 300m和900m。通过与国际标准磁性柱的对比可得: 喀什西剖面的地层沉积速率大致恒定, 西域组底界和生长地层底界年龄分别约为1.6Ma和1.4Ma; 喀什城剖面地层的沉积速率可能大致恒定, 也可能在距今1.07Ma之后明显减小, 西域组底界和生长地层底界年龄分别约为0.73Ma和1.07Ma

Fig. 3 Magnetostratigraphic results of the Kashi west section and Kashi Town section at the south limb of the Kashi anticline(see Fig. 2b for location).

图 4 喀什背斜BB'剖面地表地形、地震剖面和解译结果 a 沿BB'剖面的地形(垂直比例尺放大10倍), 由剖面两侧各1km宽的范围内极大值、平均值和极小值获得, 地形数据来自ASTER卫星30m分辨率的DEM; 浅灰色条带的范围为背斜隆升区的大致范围; 图中的地形高点偏离了背斜轴。b BB'剖面地震数据, 剖面深度由地层平均速率3 000m/s获得(剖面右侧纵坐标为双程时间); T8和剖面底部强反射层通过区域对比获得, 以此可确定古近系和中寒武统滑脱层的位置。c 通过对地震剖面BB'的解析, 共获得27个可连续追踪的反射层; 图中浅蓝色和红色线分别代表前生长地层和生长地层, 黄色条带代表生长地层底界的位置。剖面位置见图 2b

Fig. 4 Topographic profile, seismic reflection data, and interpretation results of the section BB' crossing the Kashi anticline.

图 5 总缩短量(S)、剪切缩短(Sε)和摺曲缩短(Sc)之间的关系 a 地层只发生剪切(纯剪或单剪)缩短; b 地层只发生摺曲缩短; c 地层同时发生剪切缩短和摺曲缩短。L0 变形前地层长度; L'0 变形后地层长度; L 变形后地层垂直投影宽度

Fig. 5 Relations between total shortening(S), shear shortening(Sε)and curvietric shortening(Sc).

图 6 深度-隆升面积法计算滑脱褶皱缩短量(据文献(Epard et al., 1993; 李世琴, 2009)修改) a 面积守恒的背斜横截面; b 隆升面积和距滑脱面深度的关系图

Fig. 6 A sketch showing the depth-relief area method to calculate the detachment fold shortening (adapted from Epard et al., 1993; LI Shi-qin, 2009).

图 7 喀什背斜东倾伏端的缩短和隆升历史 a 古近系滑脱层之下地层深度-隆升面积关系图; b 古近系滑脱层之上地层深度-隆升面积关系图; c 缩短量随深度的变化; d 隆升量随深度的变化。Ae 盈余面积; S -由线性拟合得到的背斜缩短量; Sc 摺曲缩短; Sε 剪切缩短; dS/dH 缩短量与地层厚度的关系; dU/dH 隆升量与地层厚度的关系

Fig. 7 Shortening and Uplift histories of the Kashi anticline.

图 8 喀什背斜沉积-隆升关系(a)和缩短-隆升关系(b) 隆升增量/沉积增量(dU/dH)和隆升增量/缩短增量(dU/dS)可能基本保持恒定, 也可能在层22之后显著减小

Fig. 8 Sediment-uplift and shortening-uplift graphs of the Kashi anticline.

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西南天山喀什背斜东倾伏端的生长演化和地貌响应: 基于地质地貌、地震反射剖面和磁性地层数据的综合分析

GROWING HISTORY AND GEOMORPHIC RESPONSE OF THE EASTERN TERMINATION OF KASHI ANTICLINE, SOUTHWESTERN TIAN SHAN: AN INTEGRATED ANALYSIS OF GEOLOGY, GEOMORPHOLOGY, SEISMIC REFLECTION PROFILE AND MAGNETOSTRATIGRAPHY

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