Middle Miocene Onset of the Litang Fault System Records Kinematic Change in Eastern Tibet

IF 3.3 1区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS Tectonics Pub Date : 2023-12-14 DOI:10.1029/2023tc007931
Kai Cao, Di Zhang, Xiaoming Shen, Junfeng Zhang, Dun Wang, Yadong Xu, Guocan Wang
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Abstract

The ∼400-km-long Litang fault system (LTFS) is a major intracontinental strike-slip fault inside the Chuandian block, eastern Tibet, but its evolution and role in accommodating the India-Asia convergence remain poorly known. Structural analysis shows that the LTFS splits into 5 strands as a left-lateral, right-stepping en-echelon pattern formed under NW-directed compression, subsequently reactivated by transtensive faults under NNE-directed extension. Displaced geological and morphological markers yield a cumulative left-lateral offset of 28.9–42.8 km. Inverse thermal-history modeling of thermochronological data of the faulted rocks reveal accelerated cooling at 38–35 Ma, 16–13 Ma, and 7–5 Ma. The late Eocene rapid cooling is ascribed to the reactivation of the Garze-Litang suture. Rapid cooling events at 16–13 Ma and 7–5 Ma record the onset of transpression and transtension of the LTFS, respectively, yielding a geologic slip rate of 2.6 ± 0.7 mm/yr. Both bifurcated geometry and slow slip rate of the LTFS since 16–13 Ma indicate diffuse deformation inside the Chuandian block, contrasting with strain localized on fast-slip strike-slip faults on the block margins. This implies a significant kinematic transition in the middle Miocene, such that the extrusion of the segmented mega-blocks has been accommodated by both localized and distributed deformation in eastern Tibet. This tectonic transition could be explained by a change in lithospheric rheology from an earlier rigid state to a viscous state underneath the Chuandian block due to thermal weakening of the lower crust. We thus reconcile the end-member geodynamic models of block extrusion and lower crustal flow in late Cenozoic times.
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中新世开始的理塘断裂系统记录了西藏东部的运动变化
长达 400 公里的理塘断层系统(LTFS)是西藏东部川滇地块内的一条主要大陆内部走向滑动断层,但人们对它的演化及其在印度-亚洲交汇中的作用仍然知之甚少。构造分析表明,LTFS在西北向压缩作用下分裂为5股,呈左侧、右侧走向的 "en-echelon "格局,随后在东北向延伸作用下被横断面断层重新激活。地质和形态标记的位移产生了 28.9-42.8 千米的累积左侧偏移。对断层岩石的热时学数据进行的逆热历史建模显示,在38-35 Ma、16-13 Ma和7-5 Ma处出现了加速冷却。始新世晚期的快速冷却被归因于甘孜-理塘缝合线的重新激活。16-13Ma和7-5Ma的快速冷却事件分别记录了LTFS转位和转张的开始,地质滑动速率为2.6±0.7毫米/年。自16-13Ma以来,LTFS的分叉几何形状和缓慢的滑动速率都表明川地块体内部发生了弥散变形,与之形成鲜明对比的是块体边缘快速滑动的走向滑动断层上的局部应变。这意味着中新世中期发生了重大的构造转变,即西藏东部的局部变形和分布变形都适应了分块巨型块体的挤压。由于下地壳的热减弱,岩石圈流变学从早期的刚性状态转变为川地块下的粘性状态,从而解释了这一构造转变。因此,我们调和了块体挤压和新生代晚期下地壳流动的末段地球动力学模型。
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来源期刊
Tectonics
Tectonics 地学-地球化学与地球物理
CiteScore
7.70
自引率
9.50%
发文量
151
审稿时长
3 months
期刊介绍: Tectonics (TECT) presents original scientific contributions that describe and explain the evolution, structure, and deformation of Earth¹s lithosphere. Contributions are welcome from any relevant area of research, including field, laboratory, petrological, geochemical, geochronological, geophysical, remote-sensing, and modeling studies. Multidisciplinary studies are particularly encouraged. Tectonics welcomes studies across the range of geologic time.
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