Abstract
The Yinchuan basin, located on the western margin of the Ordos block, has the characteristics of an active continental rift. A NW-striking deep seismic reflection profile across the center of Yinchuan basin precisely revealed the fine structure of the crust. The images showed that the crust in the Yinchuan basin was characterized by vertical stratifications along a detachment located at a two-way travel time (TWT) of 8.0 s. The most outstanding feature of this seismic profile was the almost flat Mohorovičić discontinuity (Moho) and a high-reflection zone in the lower crust. This sub-horizontal Moho conflicts with the general assumption of an uplifted Moho under sedimentary basins and continental rifts, and may indicate the action of different processes at depth during the evolution of sedimentary basins or rifts. We present a possible interpretation of these deep processes and the sub-horizontal Moho. The high-reflection zone, which consists of sheets of high-density, mantle-derived materials, may have compensated for crustal thinning in the Yinchuan basin, leading to the formation of a sub-horizontal Moho. These high-density materials may have been emplaced by underplating with mantle-sourced magma.
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1 Introduction
The Yinchuan basin is one of the Cenozoic faulted basins around the Ordos block in China, with Ordos block to its east, bounded by the Alxa block to its west, and contacts with the NE Tibetan arcuate tectonic belt to its South (Fig. 1). The Yinchuan basin is located at the northern end of the N-S trending seismotectonic zone, which has undergone intensive earthquake activities during the modern times, including a great earthquake of magnitude 8.0 in 1730 (Li and Wan 1984; Lin et al. 2015). Because of the devastating geologic hazards, previous researchers have conducted a series of investigations of active faults in the Yinchuan basin, and have determined their active timings, patterns, and phases of activity (Zhang et al. 1982; Deng et al. 1984; Liao et al. 2000; Chai et al. 2001, 2006; Lei et al. 2011, 2012).
Geological surveys refer to tectonic landforms in and around the Yinchuan basin (Zhou et al. 1985) and regional tectonic evolution in the Cenozoic (Deng et al. 1999) roughly delineated the formation age and evolution process of the Yinchuan basin. The results, however, were obtained from tectonic stress field inversion (Zhang et al. 1998, 2006; Huang et al. 2013) specifically indicated the stress states in each stage during the evolution process. Geo-thermochronology evidences got from Zircon, Apatite fission track demonstrated the absolute ages of some evolution stages (Zhao et al. 2007; Liu et al. 2010). Oil exploration in the Yinchuan basin preliminarily revealed the shallow basin structures and features of the Cenozoic strata (PGCGCOF 1992; Hou et al. 2012, 2014). The basic tectonic framework has been determined to be an almost symmetrical graben combination which is bounded by Helanshan eastern piedmont fault (F 2), Luhuatai fault (F 3), Yinchuan-Pingluo fault (F 4), and Huanghe fault (F 5) from west to east (Fig. 2).
As mentioned above, most of the earlier studies have concentrated on the surficial deposits of the basin and the shallow geology; investigations of deep geological structure, which is of great significance to understand the geodynamics of basin evolution, are relatively rare, or investigation results are not distinct enough to decipher the deep process of basin evolution. The depth of Mohorovičić discontinuity (Moho) was previously thought to have been uplifted by about 6 km under the Yinchuan basin compared with the adjacent Ordos block and Alxa block (EBGTSSB 1992). This phenomenon has been widely utilized to explain the deep geodynamics occurring during the evolution of the basin, with the uplifted Moho leading to the crustal thinning that ultimately promoted the formation of Yinchuan basin (Zhou et al. 1985; Deng et al. 1999). Deep seismic reflection profiles are an international recognized technique of revealing the fine structure of the lithosphere and are used to resolve the geology at depth (Wang et al. 2010); furthermore, images obtained from deep seismic reflection profiles are more precise and reliable than other geophysics methods. Nevertheless, a WNW–ESE trending deep seismic reflection profile crossing the Yinchuan basin carried out in 2008 clearly revealed the fine crustal structure of the Yinchuan basin (Fang et al. 2009; Feng et al. 2011) with a distinct reflection Moho that is nearly flattened, which conflicted with previous suggestion of a convex Moho (Fang et al. 2009). Therefore, the deep processes in the Yinchuan basin require a new explanation.
This article, based on a reasonable explanation of this deep seismic reflection profile, combined with previous research results, proposes a new interpretation of the geological processes occurring at depth in the Yinchuan basin. During the basin evolution process, the deep process is featured by mantle-derived magmatic underplating instead of Moho uplift as mentioned in previous works.
2 Geological setting
Our seismic profile crosses the center of Yinchuan basin (Fig. 2a), which is crescent-shaped with a width of 40–60 km, a length >180 km, and is located at the western edge of the Ordos block (Fig. 1). The west side of Yinchuan basin is connected with the Helanshan intracontinental superimposed deformation belt (Huang et al. 2015) via the Helanshan eastern piedmont fault (F 2). On the eastern side, the Yinchuan basin is bounded by Huanghe fault (F 5), which separates the Yinchuan basin from the Ordos block. The southwestern boundary of Yinchuan basin is limited by a series of Cenozoic faults, such as Sanguankou fault (F 6), Gezishan fault (F 7), and Luoshan-Niushoushan fault (F 8). In addition to these boundary faults, two other key faults-Luhuatai fault (F 3) and Yinchuan-Pingluo fault (F 4)-are found in the Yinchuan basin.
The Yinchuan basin is filled with 4000–8000 m thick Cenozoic sediments (Fig. 2b). The sedimentary center of Yinchuan basin is distributed along the eastern side of Luhuatai fault (F3), almost paralleling to the axis of the basin (Fig. 2b). Cenozoic sediments in the Yinchuan basin could be divided into five series: (1) Oligocene Qingshuiying formation (E3q), (2) Miocene Hongliugou formation (N1h), (3) Pliocene Ganhegou formation (N2g), (4) Pleistocene series, and (5) Holocene series (Q4). In addition, the Eocene series Sikouzi Formation possibly exists under the Yinchuan basin (Deng et al. 1999; Zhang et al. 2003b), although recent research has referred to the chronology of Sikouzi formation in Ningnan basin, indicating that this formation occurred after ca. 30 Ma and belongs to the Oligocene (Wang et al. 2011). Furthermore, the Ningnan basin formed earlier than the Yinchuan basin (Zhou et al. 1985), so we assumed that the Oligocene was the earliest formation timing. Previous researchers has determined the deposition rate of each phase during basin evolution process with 0.108, 0100, 0.518, and 0.615 mm/a at Oligocene, Miocene, Pliocene, and Quaternary, respectively (Zhao et al. 2007). Based on these assumptions, the Yinchuan basin is still an actively faulting basin.
3 Seismic data acquisition and processing
A total of 69 km of seismic reflection data were collected across the main faults of Yinchuan basin during the year 2008 (Fig. 2a). The explosion source with a short charge of 24 kg was used in a single well at a depth of 20–25 m, or of 18–24 kg was used in multiple short arrays at a depth of 7–15 m. SYSTEM-II seismometers of I/O corporations with 480 channels and 48 receiving traces were employed in the survey. Geophone arrays spaced at 25 m were arranged. The maximum offset is 7500 m, while the minimum offset is 0 m. The recording time is 16 s, with a sampling interval of 2 m.
Data processing adopted the FOCUS processing system. Pre-stacking processing was performed by conducting elevation and refraction static corrections, true-amplitude recovery, surface-consistent amplitude compensation, band-pass filtering, two-dimensional dip filtering, surface-consistent de-convolution, velocity analysis, residual static correction, and dip-moveout correction. An iterative procedure was employed to achieve the optimal parameters for stacking and post-stack noise attenuation.
4 Interpreted seismic reflection profile
The processed seismic section is shown in Fig. 3 which clearly revealed the fine crustal structure of the Yinchuan basin. And the preliminary interpretation of the seismic section is presented in Fig. 5. As shown in Fig. 5, the crust which is characterized by a distinct vertical stratification could be divided into two parts, i.e. upper crust (UC) and low crust (LC), at about 8.0 s TWT (two-way travel time) corresponding to a depth of about 20 km. The upper crust could be further split into two segments at 4.0 s TWT. The segment at 0–4 s TWT (0–8 km in depth) indicates distinct layered strata with a strong reflection energy, excellent continuity of strata, and clear relations of strata group. The deepest reflection horizons were revealed in the center of this seismic line (roughly between CDP 4187 and 2687), and shallowed from the center to both sides (Fig. 5). This is a typical characteristic of sedimentary basin. The segment at 4–8 s TWT (8–20 km in depth) shows almost no reflection, except for two dipping reflection zones, i.e. R 1 (Fig. 4a) and R 2 (Fig. 5), which are possibly representatives of fracture zone of Helanshan eastern piedmont fault and fracture zone of Huanghe fault, respectively. Lower crust (LC) shows relatively simple reflective features, but could be subdivided at CDP 4187 (thick dashed line) into two parts in east-west strike on the seismic section according to the reflection features (Figs. 4b, 5). The west segment is characterized by a pervasive distribution of a series of short, dipping events from 8.0 to 13.0 s TWT, whereas the east section shows three reflection interfaces roughly located at 8.0, 11.0, and 13.0 s TWT with no distinct reflection among these interfaces (Fig. 4b). This feature may be representative of two different crystalline basements under the Yinchuan basin.
The Moho, which is distinguished by a thick high reflection zone from 14 to 15 s TWT (42–43 km in depth), manifests as a nearly flattened geometric characteristic (Fig. 5). The high reflection zone consists of a series of horizontal, layered, intensive reflection events with continuing 0.6–1 s TWT. Adopting 6.4 km/s as the wave velocity of this zone (Feng 2011), this high reflection zone represents 2–3.2 km thickness of the lower crust zone, and the thickness decreases with the decreasing of the sediment thickness in Yinchuan basin (Fig. 5). The almost flattened Moho and high reflection zone existing here come into sharp conflict with general thought that the sedimentary basins possess an uplifted Moho. So we should pay special attention to this phenomenon, and this would be detailedly interpreted in the next section.
5 Discussion
Continental rift zones are long, narrow tectonic depressions in the Earth’s surface where the entire lithosphere has been modified in extension (Olesen 1995). Conventional models of rift zones include three characteristic features: (1) a surface manifestation as an elongated topographic trough, (2) Moho shallowing due to crustal thinning, and (3) reduced seismic velocity in the uppermost mantle due to decompression melting or heating from the Earth’s interior (McKenzie 1978; Ruppel 1995). Many Cenozoic continental rifts do not have all three of these characteristics mentioned above–for example, only the surface manifestation can be observed in the Baikal rift zone and the crust and mantle characteristics are not seen (Nielsen and Thybo 2009; Thybo and Nielsen 2009). A model of the seismic compressional velocity along the seismic profile across the south Kenya rift indicated that the Moho is nearly flatten, unlike with previous models (Thybo et al. 2000). Studies in the south Rhine rift graben have again confirmed a flat Moho (Brun et al. 1992). But a common feature requiring to be paid special attention is a zone of high seismic velocity or high reflection zone at the bottom of lower crust (Thybo and Artemieva 2013). The factors related to formation of this feature were speculated as the result of magmatic underplating (Thybo and Artemieva 2013), a process induced by mantle-derived magma intrusion into the lower crust in the form of sheets. Achievements of experimental simulation have confirmed that mantle-derived magma could intrude into the lower crust in the form of sheets (Deemer and Hurich 1994; Gerya and Burg 2007). So the expected Moho uplift under the continental rifts may be compensated by the high-density materials deriving from mantle by magmatic underplating, resulting in the observed high-velocity zones or high reflection zones (Thybo and Artemieva 2013).
The Cenozoic Yinchuan basin is a long, narrow tectonic depression at the west Ordos block. Meanwhile, the entire lithosphere of the Yinchuan basin is in the NW-SE extension stress field (Chen et al. 2009, 2010; Ma et al. 2010). These two characteristics are consistent with the definition of a rift basin given by Olesen (1995). In addition, there are still strong, active tectonics in the Yinchuan basin and a relatively high rate of deposition. We therefore proposed that Yinchuan basin is a Cenozoic depression with the characteristics of an active continental rifts. As revealed by seismic profile, the Moho under Yinchuan basin shows a flattened geometry. However, a high reflection zone with 2–3.2 km thickness could be observed in the lower crust of Yinchuan basin (Fig. 5). The thickness of this high reflection zone corresponds to the suggestion of McCarthy and Parsons (1994) that the thickness of layered magmatic intrusion results from magmatic underplating no more than 4 km. We therefore speculated that the formation of high reflection zone under the Yinchuan basin was attributed to magmatic underplating, by comparing this reflection zone with other zones typical of underplating.
We rarely know about material compositions of this high reflection zone, because of the untouched depth and absence of magmatic rock with information about deep earth in the surface. However, we can glimpse some clues about the material composition of the high reflection zone by comparing with typical rift zones. Typical continental rifts, such as Baikal rifts, Kenya rifts, and Rhine rift graben, have been shown to have high-reflection zones consisting of mantle-derived ultramafic and mafic magmatic rocks intruded by magmatic underplating (Thybo and Artemieva 2013). Detailed petrographic study about gabbro xenoliths sourced from crust-mantle boundary (high reflection zone in seismic profile) in the south basin and range province demonstrated that the mantle-sourced materials which intruded into the lower crust formed the 2-km-thick high reflection zone (McGuire 1994). The 3-km-thick high reflection zone in the Su-Lu area of China possibly consists of peridotite and mafic granulite by underplating during the Eocene period (Yang and Wang 2002). This kind of high reflection zones in the lower crust are pervasively revealed by seismic reflection section in the middle and lower reaches of the Yangtze river, and possibly consist of ultramafic-mafic magmatic rocks by underplating (Lv et al. 2004, 2005). Meanwhile, magmatic underplating occurred in Mesozoic in North China was considered to be the result of mantle-sourced mafic magma intruded into the lower crust (Liu et al. 2004). We are therefore more inclined to assume that the compositions of the high reflection zone in the Yinchuan basin consist of mantle-derived mafic sheets, but this could not be confirmed without more detailed petrographic information.
The precise formation timing of this high reflection zone in Yinchuan basin is difficult to obtain in the absence of related surface magmatic rocks that could be used for dating. Only a relative chronology could be speculated from some indirect evidences in the periphery of Yinchuan basin. As we can see in Fig. 5, Huanghe fault slightly offset the Moho and high reflection zone (R m). The fact that the Huanghe fault formed in Oligocene can be deduced from strata outcropping on both sides of Huanghe fault. So the high reflection zone formed earlier than Oligocene. The fine crustal structure of Hohhot-Baotou basin, which is part of the same fault basin around the Ordos block, has also been examined by deep seismic reflection profiling (Feng et al. 2015). These result shows similar reflection features to those in the Yinchuan basin, for example, the deepest Moho is seen under the deposition center without uplift, the thickness of the high-reflection zone decreases from deposition center to both sides, and both Moho and high reflection zone are offset by Cenozoic basin-controlling boundary fault. All these characteristics indicate that both the Yinchuan basin and the Hohhot-Baotou basin experienced similar deep processes. In addition, this seismic profile is near areas where there are large numbers of outcrops of Cenozoic basalts. Xenoliths included in these basalts indicated that magmatic underplating occurred in the lower crust of these areas during Late Mesozoic (158–97 Ma) (Liu et al. 2004). In addition, a great quantity of Late Yanshanian gabbros were detected under the Bayanhaote basin separated only by a mountain range from the Yinchuan basin (Zhang et al. 2003a), implying that a deep magmatic event occurred during this time. Based on this analysis, we suggest that magmatic underplating during the Late Mesozoic resulted in a high-reflection zone in the Yinchuan basin.
We obtained the information about the possible material compositions and formation timing of the high reflection zone under the Yinchuan basin so that we could propose a mechanism for the development of the basin at depth. In the Late Mesozoic, upwelling in the asthenosphere led to the partial melting of upper mantle, producing the ultra-basic or basic magma. Intrusion of these magmas into the lower crust in the form of sheets ultimately resulted in the high-reflection zone under the Yinchuan basin (Fig. 6a). As a result of isostatic compensation, the presence of high-density material in the lower crust induced the extension of upper crust, supporting the observation of extension setting during the Late Mesozoic. During the Cenozoic, the effect of the northwestward subduction of the pacific plate and the far-field effects of the northward subduction of Indian plate under the Eurasian plate resulted in the Yinchuan basin area in extension circumstance (Huang et al. 2013; Shi et al. 2015), which promoted the evolution of the Yinchuan basin (Fig. 6b). The high-density material in the high reflection zone compensated for crustal thinning in the Yinchuan basin, resulting in the almost flattened Moho.
6 Conclusions
-
1.
A 2–3.2 km thick high reflection zone was imaged in the lower crust near the Moho, which thinned as the sediment thickness decreased in the Yinchuan basin. Combined with other clues, we suggest that this high reflection zone formed by underplating with mantle-derived magma.
-
2.
In conflict with the generally accepted view of basin formation, we imaged a flat Moho under the Yinchuan basin. This feature was suggested to have been caused by the high-density material located in the high-reflection zone compensating for crustal thinning in the Yinchuan basin. This resulted in a flat Moho, rather than the expected uplifted boundary.
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Acknowledgments
We thank the editors and anonymous reviewers for their critical comments and constructive suggestions. This study was financed jointly by the SinoProbe Project of China (Sinoprobe-02-01), the National Natural Science Foundation of China (Nos. 41430213, 41274097, and 41404072), Geological Investigation Project of China Geological Survey (Nos. 1212011220260 and 12120115027101), and “Urban Active Fault Detection” of National Development and Reform Commission (No. 20041138).
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Huang, X., Feng, S., Gao, R. et al. High-resolution crustal structure of the Yinchuan basin revealed by deep seismic reflection profiling: implications for deep processes of basin. Earthq Sci 29, 83–92 (2016). https://doi.org/10.1007/s11589-016-0148-1
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DOI: https://doi.org/10.1007/s11589-016-0148-1