Jurassic–Early Cenozoic Tectonic Inversion in the Qilian Shan and Qaidam Basin, North Tibet: New Insight From Seismic Reflection, Isopach Mapping, and Drill Core Data

Cheng, Feng; Jolivet, Marc; Guo, Zhaojie; Lu, Huayu; Zhang, Bo; Li, Xiangzhong; Zhang, Daowei; Zhang, Changhao; Zhang, Hanzhi; Wang, Lin; Wang, Zhenqiang; Zhang, Qiquan

doi:10.1029/2019jb018086

Cited by 54 publications

(25 citation statements)

References 85 publications

(259 reference statements)

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“…As a result, the Karakax-Jinhongshan-Dangjin zone could have developed as a left-lateral transform margin (Yang et al, 1996), along which Kunlun-Qaidam moved northeastward relative to Tarim (Figures 11b and Due to intense overprinting by Cretaceous to Cenozoic tectonism (e.g., Yin, 2010), the Jurassic tectonic framework of North Tibet remains poorly understood. Notably, recent seismic profiling of the Qaidam basin reveals evidence of Early-Middle Jurassic growth strata bounded by normal faults (Cheng et al, 2019). This finding, in agreement with results of provenance and facies analysis of sediments (Yu et al, 2017), implies Early-Middle Jurassic extension within the Qaidam basin (Figure 10b), which possibly corresponds to pull-apart basin opening or transtensional relay zone generation, in response to sinistral slip along the ATF zone (Cheng et al, 2019).…”

Section: Tectonicssupporting

confidence: 80%

“…Similar Middle Jurassic extensional event has been inferred from surface normalsense shear zones in the eastern Altyn Tagh range (Chen, Yin, et al, 2003) (Figure 10b). These extensional records demonstrate that at least the Qaidam and eastern Altyn Tagh domains of North Tibet evolved into an extensional setting during Early-Middle Jurassic time (e.g., Cheng et al, 2019;Zuza et al, 2018). The driving force for extension was variously interpreted, as being attributed to either far-field effects of subduction processes along the southern edge of Eurasia (Cheng et al, 2019;Morin et al, 2018), or postcollisional extension following the closure of the Paleo-Tethys Ocean and the docking of the Qiangtang block (Yu et al, 2017).…”

Section: Tectonicsmentioning

confidence: 94%

“…Notably, recent seismic profiling of the Qaidam basin reveals evidence of Early-Middle Jurassic growth strata bounded by normal faults (Cheng et al, 2019). This finding, in agreement with results of provenance and facies analysis of sediments (Yu et al, 2017), implies Early-Middle Jurassic extension within the Qaidam basin (Figure 10b), which possibly corresponds to pull-apart basin opening or transtensional relay zone generation, in response to sinistral slip along the ATF zone (Cheng et al, 2019). Similar Middle Jurassic extensional event has been inferred from surface normalsense shear zones in the eastern Altyn Tagh range (Chen, Yin, et al, 2003) (Figure 10b).…”

Section: Tectonicsmentioning

confidence: 99%

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Contributions of Triassic Tectonism to Build the Northern Tibetan Plateau: Insights From Tectonic Evolution of the Jinhongshan Range, Central Altyn Tagh Fault System

Zhao

Johnston

et al. 2020

Tectonics

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Clarifying the contributions of pre-Cenozoic and especially the Mesozoic tectonism to build crustal architecture of the Tibetan plateau is important, especially for evaluating the role of Cenozoic Indo-Asian collision in creating the present-day plateau. However, how the Mesozoic tectonism evolved and its influence on the Cenozoic strain distribution remain enigmatic. We provide constraints on these issues by reporting evidence of Triassic (232-223 Ma) and Eocene crustal shortening in the Jinhongshan range of North Tibet, based on coupled structural, zircon U-Pb, and 40 Ar/ 39 Ar studies. Triassic shortening was accomplished by two stages manifested as top-SSE thrust shear (D1) followed by sinistral oblique shear along the ENE trending Jinhongshan shear zone and tight folding (D2), related to~NNE-SSW transpression under greenschist-to amphibolite-facies conditions. Such shortening occurred coevally with regional-scale magmatism, cooling, and exhumation, indicating significant Mesozoic tectonism capable of generating thickened crust and high elevation of North Tibet. We attributed the shortening to far-field stress effects of terrane collisions between Kunlun and Qiangtang, in which the comparable Jinhongshan and Dangjin shear zones might have formed a continuous, high-strain zone accommodating relative motion between Tarim and Kunlun-Qaidam. Eocene shortening (D3) is documented by ENE trending open folds and thrusts, kinematically compatible with left-lateral activity along the Cenozoic Altyn Tagh fault system. The Triassic Jinhongshan-Dangjin zone shows a spatial consistency with the Cenozoic Altyn Tagh fault system, implying that at least some segments of this Cenozoic fault system follow more ancient structures. Such evidence reinforces a decisive role of the Triassic tectonic discontinuity in localizing Cenozoic deformation.

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Section: Tectonicssupporting

confidence: 80%

Section: Tectonicsmentioning

confidence: 94%

Section: Tectonicsmentioning

confidence: 99%

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Contributions of Triassic Tectonism to Build the Northern Tibetan Plateau: Insights From Tectonic Evolution of the Jinhongshan Range, Central Altyn Tagh Fault System

Zhao

Johnston

et al. 2020

Tectonics

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“…Low‐temperature thermochronologic data reveal accelerated exhumation related to thrust faulting around the middle Miocene (Lease et al., 2011; Meng et al., 2020; Pang et al., 2019; Wang, Zheng, et al., 2020; Yu, Pang, et al., 2019; Yu, Zheng, et al., 2019; Zheng et al., 2010; Zhuang et al., 2018). However, debates still exist as to the mechanisms of the Cenozoic deformation in the entire Qilian Shan (Meyer et al., 1998; Zuza et al., 2016, 2019), relationship(s) between pre‐Cenozoic structures and Cenozoic deformation (Chen, Shao, et al., 2019; Cheng, Jolivet, et al., 2019), whether the entire Qilian Shan has experienced multi‐phased uplift (Li, Zuza, et al., 2020; Qi et al., 2016; Zhuang et al., 2011) or synchronous uplift (Yu, Zheng, et al., 2019), and whether the Qilian Shan has undergone a gradual northward propagation (Bovet et al., 2009; Cheng, Garzione, Jolivet, et al., 2019) or outward expansion in opposite directions in the Cenozoic (Pang et al., 2019). These uncertainties limit our understanding of how the Tibetan Plateau has grown and underlying geodynamic processes.…”

Section: Introductionmentioning

confidence: 99%

Topographic growth of the northeastern Tibetan Plateau during the middle‐late Miocene: Insights from integrated provenance analysis in the NE Qaidam Basin

Zheng

Zhou

et al. 2021

Basin Research

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The development history of high topography in the northeastern (NE) Tibetan Plateau is essential to test various plateau growth models and understand plateau construction. We present integrated provenance data from the NE Qaidam Basin, south of the Qilian Shan. Results show an increase in carbonate lithics, an increase in Al 2 O 3 /SiO 2 ratios, a negative shift in ε Nd values and an appearance of large amounts of Precambrian zircon grains in the period of ca. 13-8 Ma, arguing that the sediment source of the NE Qaidam Basin may have shifted from the East Kunlun Shan to the Qilian Shan during this time interval. We infer that significant topographic growth of the southern Qilian Shan occurred during the middle-late Miocene. Along with widespread middle to late Miocene deformation records across the Qilian Shan and abruptly shifts on provenance, sedimentary facies and climate indexes in its surrounding basins, present high topography of the NE Tibetan Plateau may have been established since the middle-late Miocene.

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“…Based on sedimentary and stratigraphic information obtained from Jurassic strata exposed along the southern flank of the Qilian Shan, Ritts and Biffi (2001) argued for a contractional regime under which the northern Qaidam Basin behaved as a foreland basin related to southward thrusting of the Qilian Shan. In contrast, based on interpretation of regional seismic profiles across the northern Qaidam Basin and on provenance analysis of Jurassic clastic series deposited in the northern Qaidam Basin and Qilian Shan region, some recent studies suggested that the Jurassic sedimentation and structural pattern in the northern Qaidam Basin resulted from regional extension or transtension (Lou et al, 2009;L. Wu et al, 2011;Yin, Dang, Wang, et al, 2008;Yu et al, 2017;Zuza et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Jurassic-Early Cenozoic Tectonic Inversion in the Qilian Shan and Qaidam Basin, North Tibet: New Insight From Seismic Reflection, Isopach Mapping and Drill Core Data

Cheng¹

2019

Geological Society of America Abstracts With Programs

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The pre-Cenozoic structural pattern of Asia has had a strong impact on the localization and propagation of the Cenozoic deformation that gave birth to the Tibetan Plateau. Northern Tibet represents a key area to decipher the structural and kinematic links between the Mesozoic and Cenozoic evolution of Tibet. Nonetheless, the Mesozoic tectonic setting of the North Tibet and the role that the Paleozoic inherited Altyn Tagh Fault (ATF) shearing zone played in controlling the regional tectonic pattern during the deposition of the Mesozoic strata remain controversial. This study is based on seismic reflections, isopach maps of the Mesozoic strata in the Qaidam Basin, and provenance analysis using detrital zircon geochronological and heavy mineral contents. Seismic reflections and isopach maps demonstrate that sustained strike-slip motion along the ATF during the Early to Late Jurassic induced transtensional basin formation. Further away from the main ATF (eastern parts of the Qilian Shan and the northern Qaidam Basin), transtension also occurred along major faults, although local transpression developed in relay zones. Rotation in the regional stress field induced compression and basin inversion during the Late Jurassic to Early Cretaceous. The Cenozoic sedimentary rocks in these regions display widespread growth strata and angular unconformities characteristic of compression. This is consistent with topographic changes marked by sediment source variation evidenced by detrital zircon geochronology and heavy mineral analysis. We propose that the mechanism driving the Jurassic extension/transtension in North Tibet could be related to far-field effects of subduction processes along the southern margins of the continent.

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Jurassic–Early Cenozoic Tectonic Inversion in the Qilian Shan and Qaidam Basin, North Tibet: New Insight From Seismic Reflection, Isopach Mapping, and Drill Core Data

Cited by 54 publications

References 85 publications

Contributions of Triassic Tectonism to Build the Northern Tibetan Plateau: Insights From Tectonic Evolution of the Jinhongshan Range, Central Altyn Tagh Fault System

Contributions of Triassic Tectonism to Build the Northern Tibetan Plateau: Insights From Tectonic Evolution of the Jinhongshan Range, Central Altyn Tagh Fault System

Topographic growth of the northeastern Tibetan Plateau during the middle‐late Miocene: Insights from integrated provenance analysis in the NE Qaidam Basin

Jurassic-Early Cenozoic Tectonic Inversion in the Qilian Shan and Qaidam Basin, North Tibet: New Insight From Seismic Reflection, Isopach Mapping and Drill Core Data

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