Abstract
The eastern Tibetan plateau has been getting more and more attention because it combines active faults, uplifting, and large earthquakes together in a high-population region. Based on the previous researches, the most of Cenozoic tectonic activities were related to the regional structure of the local blocks within the crustal scale. Thus, a better understanding of the crustal structure of the regional tectonic blocks is an important topic for further study. In this paper, we combined the simple Bouguer gravity anomaly with the Moho depths from previous studies to investigate the crustal structure in this area. To highlight the crustal structures, the gravity anomaly caused by the Moho relief has been reduced by forward modeling calculations. A total horizontal derivative (THD) had been applied on the gravity residuals. The results indicated that the crustal gravity residual is compatible with the topography and the geological settings of the regional blocks, including the Sichuan basin, the Chuxiong basin, the Xiaojiang fault, and the Jinhe fault, as well as the Longmenshan fault zone. The THD emphasized the west margin of Yangtze block, i.e., the Longriba fault zone and the Xiaojiang fault cut through the Yangtze block. The checkboard pattern of the gravity residual in the Songpan-Garze fold belt and Chuandian fragment shows that the crust is undergoing a southward and SE-directed extrusion, which is coincident with the flowing direction indicated from the GPS measurements. By integrating the interpretations, the stepwise extensional mechanism of the eastern Tibetan plateau is supported by the southeastward crustal deformation, and the extrusion of Chuandian fragment is achieved by Xianshuihe fault.
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1 Introduction
The eastern Tibetan plateau has been divided into three sub-units by four major left-lateral strike-slip faults, including the red river fault, the Xianshuihe fault, the Kunlun fault, and the Haiyuan fault (Fig. 1b). Based on the observed Global Positioning System (GPS) measurements, the Tibetan plateau is dominated by lateral movement (Gan et al. 2007). These four dominant left-lateral strike-slip fault systems control the directions of extrusion from southeast to northeast (Fig. 1a) (Wang et al. 2014; Tapponnier et al. 1986, 2001). With the exception of the Zoige basin, the average elevations of the Songpan-Garze fold belt and Chuandian fragment are both above 4 km. In the northeastern Kunlun fault and the southeastern Chuandian fragment, the elevation decreases smoothly toward the northeast and southeast. The Longmenshan fault belt stands out from the Sichuan basin and eastern Tibet because of its high topographic gradient (Clark and Royden 2000). The recent 40-year earthquakes were located along the major faults at depths of 40 km and a shallower depth dominantly between 20 and 30 km (Fig. 1b). Based on the focal mechanism, the Sichuan basin is under compression from eastern Tibet, and the inner part of the Chuandian fragment extends in a southeast direction (Wang et al. 2014). The general consensus is that the 2008 Wenchuan earthquakes resulted from the convergence between the eastern Tibetan plateau and the Sichuan basin divided by the Longmenshan fault zone (Burchfiel et al. 2008; Hubbard and Shaw 2009; Wang et al. 2011). The lower velocity layer, which appears as a featured character in the crust, has been discovered by different types of seismic data (e.g., Liu et al. 2014; Zhang et al. 2011; Yang et al. 2012; Li et al. 2014; Bao et al. 2015). The research of Xu et al. (2015) shows the lower velocity zone contributes to the regional uplifting, earthquakes, and crustal thickening. However, the distribution of lower velocity layer actually appears with discrete and uneven thickness. In addition, none of the proposed models can explain all of the geological and geophysical observations in this area, and the section of lithosphere that was involved in the local tectonic activity has not been identified (Tapponnier et al. 2001; Hubbard and Shaw 2009; Wang et al. 2011; Royden et al. 1997, 2008). In this paper, we view the crust as a whole and focused on the regional crustal feature in a map view to determine the lateral contact relationship between crustal structure and tectonic activity.
2 Geological settings
The Chuandian fragment is next to the Songpan-Garze fold belt and Sichuan basin and is bounded to the northeast by the Xianshuihe-Xiaojiang fault (Wang et al. 1998). As part of the rigid and stable Yangtze Craton, the Sichuan basin was cut through by the Xianshuihe-Xiaojiang fault during the late Cenozoic (Roger et al. 1995). The extrusion and clockwise rotation of the Chuandian fragment are supported by paleomagnetic measurements, GPS measurements, and the focal mechanisms of the earthquakes (Chen et al. 1995; Molnar and Lyon-Caen 1988; Holt et al. 1991). The Chuxiong basin is similar to the Sichuan basin in that both possess characteristics of the Yangtze craton, which contains Early Proterozoic crystalline basement (Fig. 1b) (Wang et al. 1998). The Songpan-Garze fold belt is located in the eastern part of the Tibetan plateau and is separated from west of the Sichuan basin by the Longmenshan fault zone (Fig. 1b) (Burchfield et al. 1995). The Songpan-Garze terrane is filled with thick Triassic flyschoid rocks due to the closure of Paleo-thethys Ocean during the Early Jurassic (Roger et al. 2010).
The Red river fault zone is the major geological boundary between the Indo-china block and the South China Platform (Fig. 1a) (Mazur et al. 2012). The Red river fault zone has two phases of strike-slip deformation (Tapponnier et al. 1986; Leloup et al. 2001). The early-phase tectonic activity along the Red river fault zone was left-lateral motion between the latest Eocene and early Miocene (Tapponnier et al. 1986; Leloup et al. 2001; Lacassin et al. 1997; Morley 2002). The latest phase changed to right-lateral slipping at 5 Ma with approximately 25 km of displacement (Tappinnier and Molnar 1977; Allen et al. 1984; Replumaz et al. 2001; Leloup et al. 1993).
The Xianshuihe-Xiaojiang fault zone is one of the most active NW-trending fault zones within the southeastern margin of the Tibetan plateau (Fig. 1a) (Wang et al. 1998). It caused several large earthquakes with left-lateral motion and magnitudes exceeding M S 7.0 because of the intra-continental deformation during the Cenozoic (Deng et al. 2007; Guo et al. 2012; Molnar and Tapponnier 1978; Avouac and Tapponnier 1993). The fault zone has up to 100 km of total displacement with four branches and extends for more than 1400 km (Burchfield et al. 1995; Wang et al. 1998; Wang et al. 2009). The Xianshuihe-Xiaojiang fault zone can be divided into two phases: an early stage from 13 to 5 Ma and a late stage from 5 Ma until present. The Xiaojiang fault was initialed from the continuous clockwise rotation of the eastern Indo-China syntaxis (Wang et al. 2009).
The Kunlun fault is one of the major structures in the active deformation history of the Tibetan plateau (Avouac and Tapponnier 1993). The fault also acts as the northern boundary of the Songpan-Garze terrane along the Anyemaqen suture (Yin and Harrison 2000) and connects with the Mianlue suture in east (Meng et al. 2005). It extends nearly 1500 km (Fig. 1) and acts as a transition from flat, high-elevation plateau to mountain-basin alternate terrain (Kirby et al. 2007). Along the southern margin of the Qaidam basin, the Kunlun Mountain uplifted between ~35 and ~20–15 Ma (Fig. 1b) due to crustal shortening that occurred during that time along with the acceleration of exhumation near 15 Ma (Yuan et al. 2013; Lu et al. 2012). The initial left-lateral slip of the Kunlun fault zone began at ~20–15 to ~8 Ma on the E–W strike in the western part of the fault system (Jolivet et al. 2003). The total displacement is difficult to estimate because of the discontinuities of the fault; however, the deflection of the Yellow river in the eastern part of the fault indicates that the displacement is more than 85 km (Gaudemer et al. 1989; Van der Woerd et al. 2002). Kirby et al. (2007) calculated the slip rates along the eastern 150 km of the Kunlun fault based on the displaced fluvial terrace risers and 14C ages of the terrace material; the slip rates decrease from >10 to <2 mm/year. Additionally, they speculated that the shortening across northeastern Tibet resulted in the rotation of the eastern part of the Kunlun fault. In the present study, we build an evolution model to explain how the crustal deformation of northern Tibet caused the rotation of the eastern part of the Kunlun fault between Maqen and Maqu (Fig. 1b).
The 1000 km-long left-lateral east-striking Haiyuan fault system extends from the central Qianlianshan in the west to the Liupanshan to the east (Fig. 1b). This fault system accommodates the deformation caused by the India-Eurasia collision (Jolivet et al. 2012). The Haiyuan fault system triggered two M W 8 earthquakes, the Haiyuan earthquake in 1920 and the Gulang earthquake in 1927 (e.g., Deng et al. 1986; Xu et al. 2010). The Haiyuan earthquake in the eastern section of the Haiyuan fault was caused by strike-slip movement with a rupture of 220 km. In the western end of the Haiyuan fault, the Gulang earthquake was triggered by south-dipping thrusting. Previous studies on the focal mechanism show that the Haiyuan fault mainly dips southwest and is thrusting at the connection of the southeastern end of the Qilianshan. It then transforms into a sinistral strike-slip faulting eastward (Fig. 3a). The Holocene slip rate of the Haiyuan fault is 19 ± 5 mm/a in west (Lasserre et al. 2002) and 4.5 ± 1 mm/a on average (Li et al. 2009).
The Longmenshan fault zone was reactivated during the Cenozoic, which contributed significantly to the uplift of the Tibetan plateau. According to GPS measurements, no significant active convergence (<4 mm/year) of the Longmenshan belt was recorded relative to the Sichuan basin (Zhang 2013). However, the 2008 Wenchuan earthquake occurred due to the significant accumulation of stress along the Longmenshan fault zone. Results from fission track dating documented the reactivation of the Wenchuan and Beichuan faults during the Cenozoic (Xu et al. 2008). Additionally, the Beichuan fault has been the major active structure of the Longmenshan fault zone since the late Miocene. It was activated during the 2008 Wenchuan earthquake and possesses an average uplift rate between 0.7 and 1.2 mm/year, with an estimated initiation age between 5 and 12 Ma (Burchfiel et al. 2008). At a regional scale, Wang et al. (2012) proposed two major rapid exhumation patterns: a slow exhumation during the early Cenozoic and two episodes of rapid exhumation (30–25 and 15–8 Ma). The current exhumation rate is constrained at a value less than 0.5 mm/year (Wang et al. 2012). The highest density of large earthquakes is concentrated along the Longmenshan fault zone in this area with focal depths ranging from 10 to 30 km (Xu et al. 2015).
3 Data and methods
In this study, we applied the inversion of Bouguer gravity anomaly with previously reported local seismic data to extract the gravity anomaly produced by the crust.
3.1 Seismic data
The SinoProbe-02 series of seismic experiments on both refraction and reflection profiles was a recent ambitious effort to investigate the seismic structure of the lithosphere beneath China (Dong et al. 2011). Among the studied profiles, the profiles across the Longmenshan area were a main focus of the experiments due to the need to better understand the tectonics and earthquake hazards in the region. However, the deployment of seismic recorders and sources has proven difficult due to the rugged topography, limited road access, and landslides from the 2008 earthquake. Nonetheless, we successfully completed these seismic profiles, which have been reported in two articles (Guo et al. 2013, 2014). We aimed to determine the regional crustal characteristics of this area and image the structures of the eastern edge of Tibet, the Longmenshan, and the westernmost Sichuan basin. This allowed us to obtain first-hand data on the structural features in the transition zone from the eastern Tibetan plateau [Songpan-Garze terrane (SGT)] across the western Yangtze Proterozoic block to the Sichuan basin. In addition, we collected a 400-km-long refraction and wide-angle reflection profile (Fig. 1b) during the seismic experiment. In total, we deployed 355 TEXAN seismic recorders at a station spacing of 1.5 km. We initially designed a straight-line spread to obtain seismic refraction data. However, this straight-line spread was eventually altered to follow a highway due to the severe topography. Refraction data were obtained from 12 sources ranging in size from 2000 to 500 kg. In the final analysis, only 10 of the 12 sources were used due to the low signal-to-noise ratio of the other two. Figure 2 shows the final velocity model (Xu et al. 2015).
3.2 Gravity data
The gravity anomaly data employed in this study were obtained from the International Center for Global Earth Models. These data were collected through the long term archiving of existing global gravity field models, and the resolution is 0.1° × 0.1° (http://icgem.gfz-potsdam.de/ICGEM/Service.html), which enables the calculation of gravity functions from the spherical harmonic models on freely selectable grids. Simple Bouguer gravity anomaly values were downloaded and mapped with the Geosoft/Oasis Montaj processing and analysis package using a Bouguer reduction density of 2.67 g/cm3. However, the density value for the sediments was determined to be between 2.3 and 2.4 g/cm3 based on the final seismic velocity from the wide-angle reflection and refraction seismic data and the application of Gardner’s rule (Gardner et al. 1974) to estimate density from seismic velocity. As a result, the Bouguer correction was redone using a density of 2.35 g/cm3. After this reduction, the new simple Bouguer gravity anomalies in the SGT were obtained. These values were about ~30 mGal less negative than the original data. The resolution of the elevation values employed in this calculation was reduced from the Shuttle Radar Topography Mission (SRTM) data, which have a resolution of 3 arc-seconds, because the resolution of the simple Bouguer gravity anomaly is low.
3.3 Inversion of gravity data
The regional simple Bouguer anomaly is strongly controlled by the crustal thickness (Fig. 3a). In this study, we aim to identify the characteristics of structures within the crust; thus, the anomaly of Moho depth has been removed. The Moho depth was determined from the results of the receiver function (Fig. 3a) (Xu et al. 2013; Sun et al. 2012).
The integrated 2D gravity modeling was performed during the SinoProbe-02 project (Xu et al. 2015). The gravity model (Fig. 3c) shows that the trend of the simple Bouguer anomaly is consistent with that of the Moho depth, indicating that it is strongly controlled by the variations in crustal thickness. After minor density iterations in the upper crust guided by the seismic results, it is clear that the thickness of the Triassic Songpan-Garze flysch increases from east to west, where the greatest depth is about 12 km. Aided by thrusting, the base of the sediments deepens beneath the Longmenshan fault zone (LMSFZ) and shallows toward both the Sichuan basin and the SGT. To fit the gravity data, an upper-crustal higher density lens was inserted under the sediments in the Minjiang fault zone area. Both the middle and lower crusts have variable thicknesses, likely due to the eastward compression against the rigid Sichuan basin in this area. The thickest middle crust appears immediately to the west of the LMSFZ, while the thickest lower crust appears beneath the SGT. Therefore, we suggest that the thickening of the middle crust west of the LMSFZ is caused by the eastward compression, which is blocked by the stable rigid lithosphere of the Sichuan basin.
The gravity forward modeling used an average density of 2.82 g/cm3, which was calculated from the integrated 2D gravity modeling results (Fig. 3e). The forward modeling results (Fig. 4a) clearly show the same trend with Moho depth. However, the distortions (relatively shallow) in the Songpan-Garze fold belt and the Chuandian fragment (Fig. 3a) are not shown in the forward modeling results (Fig. 4a). Figure 2b shows the results of the simple Bouguer anomaly after the reduction of crustal thickness. The research area is composed of several blocks, and the boundaries on the surface were identified as faults (Wang et al. 2014; Taylor and Yin 2009). The total horizontal derivative (THD) of the gravity anomaly has been suggested for use as an edge detector (Cooper and Cowan 2006). THD is defined as
where (∂f/∂x) and (∂f/∂y) measure the rate of change of the potential fields in the X and Y directions, respectively.
4 Results
In general, the residual of the crustal gravity anomaly (Fig. 4b) has the same relief as the regional topography (Fig. 4d). The Songpan-Garze fold belt has the lowest gravity anomaly (Fig. 4b) because of its huge sediment thickness (Roger et al. 2010; Liu et al. 2013). Most thrust faults fit the trend of the gradient of the gravity anomaly. The Garze-Yunshu fault, Xianshuihe fault, and Kunlun fault are ambiguous on the crustal gravity anomaly (Fig. 4b). The high gravity anomaly in the Chuxiong basin is separated from the Sichuan basin by the Xianshuihe-Xiaojiang fault. This shows that the crustal composition of the Chuxiong basin is similar to that of the Sichuan basin (Wang et al. 2014). The low gravity anomaly in the Songpan-Garze fold belt and Chuandian fragment has a checkerboard-like pattern, which shows that the crust is undergoing a southward and SE-directed extrusion in the eastern Tibetan plateau. This anomaly shows the same direction as the strain rate field based on GPS velocities (Gan et al. 2007). After the Moho reduction, the gravity anomaly is still in a mirror-shape (Fig. 4b). The average density of the crust increases from the Songpan-Garze fold belt to the Sichuan basin (Fig. 3d); thus, the average density of thicken crust is lower than normal crust.
The THD of the gravity anomaly shows that the western part of the Longmenshan fault zone is a transition zone between the Sichuan basin and the Songpan-Garze fold belt. The Longriba fault zone acts as the western boundary of this transition zone (Fig. 4d) and could represent the western margin of the Yangtze block (Guo et al. 2015). The transition zone continues in the southwestern direction and extends to the northwestern region of the Chuxiong basin. The Lajishan thrust fault and Jishishan thrust fault are outstanding in the northern Tibetan plateau. Within the Songpan-Garze fold belt, the gradient of the gravity anomaly does not embody any strike-slip fault zones.
5 Discussion
The residual of the crustal gravity anomaly has two features: (1) it is better correlated with the topography than with the Moho depth and (2) it is more consistent with thrust faults than with strike-slip faults. A previous study (Xu et al. 2015) demonstrated that uplift can occur under continuous convergence along the thrust fault; however, crustal thickening requires a strong and rigid block to act as a backstop. Thus, the crust is thicker in the northwest of the Chuxiong basin and Sichuan basin owing to fact that the Songpan-Garze fold belt is softer than the Yangtze block. The strain accumulates along the thrust fault (Xu et al. 2015), producing faulting, thickening, and uplift in the soft block.
Based on the analysis, we propose an evolution model in this area (Fig. 5). The model is generally proposed according to the lateral extrusion model (Tapponnier et al. 2001). The Red river fault acts as a left-lateral strike-slip fault between 35 and 15 Ma. However, after 15 Ma, the Red river fault switched to a dextral strike-slip fault (Lacassin et al. 1997; Tapponnier et al. 2001), and the Songpan-Garze fold belt became shortened and thickened. On the other hand, the Longmenshan fault zone and the Jinhe fault zone were the eastern boundary of the Tibetan plateau before 17 Ma (Wang et al. 2009). After 17 Ma, the Songpan-Garze fold belt began to be cut by the Xianshuihe fault zone. The Jinhe fault was active between 17 and 5 Ma, and, according to a previous study, the Jinhe fault was a transpressional structure at the southern end of the Xianshuihe fault zone during this time (Wang et al. 2012). The crustal extrusion resulted in the thrusting of the Songpan-Garze fold belt toward the Sichuan basin along the Longmenshan fault zone. A major phase of exhumation of the Longmenshan fault zone started at 8–11 Ma (Godard et al. 2009). The Kunlun fault zone is the northern boundary of Songpan-Garze fold belt, and the initiation age becomes younger toward the east (Yuan et al. 2013).
6 Conclusions
Based on our research, the crustal gravity residual is compatible with the topography and distribution of regional tectonic units, including the Sichuan basin, Chuxiong basin, Xiaojiang fault, Jinhe fault, Longmenshan fault zone, Longriba fault zone, and the thrust faults in the northern Tibetan plateau. Combined with previous research suggesting that the Songpan-Garze fold belt is easily deformed against a rigid block (like the Yangtze block), high elevation and thick crust were built up accordingly as a result. The Longriba fault zone could be the western boundary of the Yangtze block, and the Songpan-Garze flysch overlays the western Yangtze block between the Longmenshan fault zone and the Longriba fault zone. The inner crustal north-south-directed extension in the Chuandian fragment can be identified by the focal mechanism and crustal gravity residual. The Xiaojiang fault cut through the Yangtze block. With the exception of the Xiaojiang fault, few strike-slip faults are correlated with the crustal gravity residual. Together, these interpretations indicate that the stepwise extensional mechanism of the eastern Tibetan plateau is supported by the crustal scale deformation.
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Acknowledgments
We would like to acknowledge the anonymous reviewers for their valuable comments on earlier versions of this manuscript. This work was supported by the National Natural Science Foundation of China (Grant Nos. 41430213 and 41304064).
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Xu, X., Gao, R. & Guo, X. Relationship between the regional tectonic activity and crustal structure in the eastern Tibetan plateau discovered by gravity anomaly. Earthq Sci 29, 71–81 (2016). https://doi.org/10.1007/s11589-016-0142-7
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DOI: https://doi.org/10.1007/s11589-016-0142-7