Abstract
Within the lower Wumishan Formation at the eastern edge of the Tai-hang Mountains in North China, a ~ 10 m stratigraphic interval contains alternately "bright and dark" laminites with enigmatic loop structures (2.5–27.5 cm in length and 0.6–12 cm in height), preserved in cross-sectional and named "loopites" in this study. The loopites are composed of cores and annulate laminations. Based on the different morphologies, they can be divided into three different types: type I, II and III. Although the loopites are similar to the loop beddings, the formation mechanisms are different. The former is possibly microbially induced sedimentary structures (MISS), while the loop beddings preserve evidence of soft-sediment deformation structures (SSDS) such as boudinage or chain structures, joints and small-scale tensional faults. All three types of loopites have cores. The type I core is made up of relicts of previous microbial mat and the microhighlands, while the type II and III loopites have cores defined by debris and rock fragments. The cores are completely wrapped by microbial mats of later generation. Thus, we can conclude that the formation of loopites is due to the growth, wrapping and deposition of microbial mats, while loop beddings are generated by external triggering mechanism such as earthquake. Furthermore, the discovery and possible formation of loopites may provide a new type of MISS and indicate a stable, anoxic and carbonate-supersaturated environment favorable for microbial mats to form annulate structures, which are controlled by illumination, microtopography and hydrodynamics.
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Introduction
The Mesoproterozoic strata, widely deposited in North China, record the detailed geological history of the Earth’s evolution in the ancient world from 1.8 to 0.8 Ga (Ying et al. 2011; Tang et al. 2016; Tan et al. 2021). In particular, the widely distributed and well-preserved outcrops of the Mesoproterozoic Wumishan Formation preserve abundant natural information, including paleogeography, paleoclimate, paleontology, paleotectonics, and paleomagnetism, and thus provide excellent research materials for geologists from all over the world. (Zhang 1985; Chen et al. 2013; Li et al. 2013; Mei and Maurice 2013; Tang et al. 2014, 2015; Shen et al. 2018; Yang et al. 2022). The Wumishan Formation is renowned for its large thickness (the thickest outcrop > 3000 m) of dolomitic and various microbial deposits whose main types include various forms (laminated, wavy, cone-shaped, columnar and domal) of stromatolites, thrombolites, and oncolites (Cao 1991; Mei et al. 2008; Tang et al. 2013b; Lu et al. 2019, 2021; Zhai et al. 2023). Moreover, it contains a variety of different types of soft-sediment deformation structures (SSDS) and microbially induced sedimentary structures (MISS) which have attracted the attention of geoscientists in the last three decades.
The earliest record of SSDS in the Wumishan Formation was found in the Xishan section, which is located northwest of Beijing (Song 1988). There are more than 15 types of SSDS (e.g., liquefied mixed layers, diapirs, liquefied veins, liquefied convolute beddings, plate-spine breccia structures, thixotropic diapirs, thixotropic wedges, thixotropic veins, mound-and-sag structures, ball-and-pillow structures, loop beddings, undulated deformations, deformed stromatolites, load casts, flame structures, and chrysanthemum structures) which have been identified in the Wumishan Formation. The major triggering mechanisms in the Wumishan Formation are earthquakes and storms (Xie et al. 1997; Zhang et al. 2007; Qiao and Gao 2007; Qiao and Li 2009; Ettensohn et al. 2011; Su and Sun 2011, 2012; van Loon and Su 2013; Qiao et al. 2017), same as the major perspectives of the triggering mechanisms of SSDS in the world (van Loon 2009; Shanmugam 2017). However, with the development and deepening of research on SSDS, microbial mats and their related structures have usually been observed to be associated with SSDS. Especially in the Proterozoic, microbial mats could be treated as a key factor influencing soft-sediment deformation directly because they were the only biological agents at that time, and their growth could enhance or limit the formation of SSDS (Obermeier 1996; Harazim et al. 2013; Banerjee et al. 2014). Although they were not the major mechanism, they definitely can be a special proxy for representing and recording the SSDS in carbonate and siliciclastic rocks (van Loon and Su 2013; Hill and Corcoran 2018). Thus, in the Mesoproterozoic Wumishan Formation, the microbial mats contributed to the morphologies and perhaps the formation of some SSDS.
The earliest report on loop beddings can be credited to Bradley (1931), which was about lacustrine oil-shale deposits displaying loop beddings from the Eocene Green River Formation, western USA. In addition, a large number of records on the loop beddings had been marked on the different periods and lithologies in the following decades, such as the Devonian and Miocene shales, the Paleogene siltstones and mudstones, and the Ordovician carbonates (Gibling et al. 1985; Trewin 1986; Tian et al. 2006; Yuan et al. 2006). However, the first record of loop beddings in the Wumishan Formation in China was reported by Qiao and Gao (2007); additionally, Qiao and Li (2009) and Su and Sun (2011) documented other loop beddings of the Wumishan Formation in the different outcrops. The origin of the loop beddings is interpreted as the extensional deformations induced by weak earthquakes when the entire laminated soft deposits have not yet been liquefied in a lentic environment (Cavlo et al., 1998; Rodríguez-Pascua et al. 2000). Its cross-sectional view contains closed pseudoconcentric annular layers, and the long axis is parallel to and the short axis is perpendicular to the strata. In addition, the loop beddings usually appear in a chain shape; moreover, the joints present an X-shaped fracture that is caused by tension.
In this paper, we report a problematic annulate structure, which is identified in alternately "bright and dark" laminites of the Wumishan Formation, revealing similar morphological features and forming conditions of the loop bedding, whose laminations are composed of dark layers with high algal matter and bright layers of carbonate particles (Tang et al. 2014). However, it usually appears alone and maintains a good shape of a cross-sectional pseudoconcentric cylinder with no X-shaped fractures on the joints. Meanwhile, its formation is related to microbial activities. For example, for the different mechanisms of SSDS and MISS, one is the "external" force, such as earthquakes, tsunamis and storms, and the other is the "internal" force, which is the cohesiveness from itself. The essential difference between the loop bedding and the problematic annulate structure is the mechanism. Therefore, we named this annulate structure "loopite" and tried to dig into the origin of this structure to determine if it is a special type of loop bedding or a new type of MISS.
Geological setting
Paleoenvironment for the growth of microbial mats in the Wumishan period
Since ~ 1.8 Ga, the breakup of the Columbia supercontinent (Zhao et al. 2003; 2004; 2011) promoted intraplate rifting in the northern part of the Sino-Korean plate to form the Yanliao aulacogen. The development of the epicontinental sea in the Yanliao aulacogen laid the foundation for the deposition of giant thick microbialites in North China. Moreover, the most extensive sea basin of the Yanliao aulacogen was finally formed in the Wumishan period (Lu, 2002; Qiao and Gao 2007); additionally, previous paleomagnetic and paleontological studies of the North China craton showed that it was located near the equator in the Wumishan period (Zhang, 1980; Zhang et al. 1991, 2012), and the paleoclimate was dry and hot (Yan and Liu 1998), with much higher CO2 and lower O2 concentrations than today (Kaufman and Xiao 2003). Thus, it provides the most favorable conditions for microbial growth. In addition, the O2 content in the Proterozoic seawater showed some features of zonation (Canfield 1998), which means that the lower subtidal zone may have been in an anoxic state; the upper subtidal and lower intertidal zones were mainly oxidized with an occasionally anoxic state; and the upper part of the intertidal zone and the supratidal zone were in an oxidized state (Tang et al. 2011; Tang, 2013a). Hence, it can be speculated that the stable and continuous microbial mats were prone to grow in the lower subtidal zone with low energy and anoxic conditions.
The Wumishan Formation
The exposed outcrops of the Mesoproterozoic Wumishan Formation in North China record sedimentary information between ~ 1.52 Ga and ~ 1.47 Ga (Li et al. 2014; Tang et al. 2016), and their thicknesses range from 554.82 m to 3416 m (Zhao et al. 1997; Li et al. 2014) with a decreasing trend from northeast to southwest. The Wumishan Formation is dominated by peritidal carbonates, and the major types of lithologies include massive micritic dolostone, flat, wavy laminated to stromatolitic dolostone, argillaceous dolostone and chert bands and nodules (Fig. 1). The various types of dolostones were deposited under a range of subtidal to supratidal environments (Zhao et al. 1997; Tang et al. 2013a). In general, due to the exposure and the influx of siliciclastic sediments, the microbial mats could develop various forms via growth, destruction and decay. As a result, the MISS were usually found in the intertidal to supratidal zone. However, the loopites are all identified in the relatively thick, intensive and multilayered intervals of laminites that lack MISS. Thus, the loopites were not formed in the same sedimentary environment as the MISS. In addition, stable, continuous and multilaminated biofilms require weeks to months to form (Hill and Corcoran 2018) and must be settled in a stable environment with low energy and low exposure, which supports that loopites are formed in a subtidal environment by the deposition of alternating microbial mats and carbonate particles.
Methods
Fieldwork was conducted in the Wumishan Formation of the Yixian section (N39°8′57″, E115°16′22″), Yixian County, Hebei Province, North China, which is located on the eastern margin of the Tai-hang Mountains, approximately 20 km southwest of Yixian County (Fig. 2A, B). The Wumishan Formation in the Yixian area has unconformable relationships with the underlying Gaoyuzhuang Formation and the overlying Tieling Formation (Fig. 2C). The thickness is approximately 1450 m, and four members (members I–IV) are subdivided in this formation. The lithologies are briefly described in Members I–IV (from bottom to top) as follows: (1) terrigenous clastic rocks on the bottom, dark gray to gray horizontal to wavy-bedded micritic dolostones with cherts; (2) gray to light-gray massive micritic dolostones and algal dolostones with cherts; (3) dark-gray thick-bedded stromatolitic dolostones with thrombolites and cherts; and (4) light-gray thick-bedded dolostones intercalated with cherty bands. Field photos were taken, and rock samples were collected in situ. Thin sections were made of selected specimens for detailed petrographic observation.
Results
Soft-sediment deformation structures (SSDS)
With the tectonic and sedimentary conditions of intraplate rifting and epicontinental sea, the Wumishan Formation in the Yixian section preserves a wide variety of SSDS. Based on the observations, seven different types of SSDS, including mound-and-sag structures, ball-and-pillow structures, load structures, liquefied veins, plate-spine breccias, convolute beddings, and undulate deformations, have been identified in the Wumishan Formation in the Yixian section, and some apparent features of SSDS are associated with microbial mats.
Mound-and-sag structures
Mound-and-sag morphology in the Wumishan Formation usually develops in dark-gray massive micritic dolostones (Fig. 3A). The typical features of mound-and-sag structures are alternating synclines and anticlines that display different thicknesses of internal layers. The layer is thinner in the mound and thicker in the sag, with undeformed overlying and underlying units.
Ball-and-pillow structures
Ball-and-pillow structures are usually found in the lower part of the Wumishan Formation in the Yixian section. The lithologies of ball-and-pillow structures can be divided into three obvious segments from bottom to top (I, II, III) (Fig. 3B). Segment I is approximately 11 cm in height and comprises light-gray massive micritic dolostones with little lamination and an isolated nodular chert. Segment II (13 cm in height) is dominated by pillow structures and composed of light-gray micritic dolostones with gray curly laminations. In addition, a black cherty subrounded ball structure (8 cm in height, 7 cm in width) was identified in segment II. With the effect of this ball, downlaps of curly laminae occurred at the bottom of the ball. Segment III (> 3 cm in height) contains dark-gray fine-grained cherty dolostones, which are incompletely displayed in Fig. 3B. The grain size becomes increasingly coarser from segments I to III, which means that the overlying segment has a larger density than the underlying segment.
Load structures
Load structure is a liquefaction deformation structure, which is an important type of SSDS. The deformation mainly occurs at the contact interface where lithology changes, and the major deformation mode is that the sediments move upward and downward (Qiao et al. 2017). In general, the load structure is formed by the overlying denser sediments sink into the less dense sediments. But a unique load structure has been recognized in the lower part of the Wumishan Formation in the Yixian section. The uniqueness seems to be that the less dense sediments squeezed into the underlying denser grained sediments. The observed overlying whitish micritic dolostones sank into the light-gray thrombolitic (coarser) dolostones (Fig. 3C).
Liquefied veins
Liquefied veins are one of the most numerous deformation structures in the study area. Vein-type structures are formed in the interbedding of dark and light color layers dolostones (Fig. 3D). The bright laminations are composed of carbonate particles, and the dark laminations are dark-gray algal dolostones that are composed of microbial mats. The sizes of liquefied veins are approximately a few centimeters to 20 cm. Two types of liquefied veins are identified: horizontal veins, which flow along the bright laminations, and vertical veins, which flow vertically towards the laminations.
Plate-spine breccias
The first record of plate-spine breccias in China was from Song (1988) in the Wumishan Formation of Ming Tombs section on the northwest side of Beijing. After that, such breccias are widely identified and observed in the Mesoproterozoic Formations in the North China craton. Plate-spine breccias or accordion folds (Ettensohn et al. 2011), a common type of SSDS, can be found in all members of the Wumishan Formation in the Yixian section. The plate-spine structure is formed in thin laminated dolostone or cherty dolostone layers. Because of the strong compression, the plate-like and band-like soft-sediment layers are squeezed from a horizontal position to an inclined and even vertical position. The lithologies of these breccias could be the same as those of their parent rocks, such as dark-gray chert dolostone and light-gray micritic dolostone (Fig. 3E), and the lengths of breccias range from 0.5 cm to more than 5 cm. In the Yixian section, this type of deformed structure is usually observed between two undeformed layers.
Convolute beddings
Convolute beddings are most common in the interbedded light-gray micritic dolostones and black algal dolostones with thin lamination intervals in the lower part of the Wumishan Formation in the Yixian section. These beds display complex syn-sedimentary folds that are highly deformed and disrupted and show dimensions up to 8 cm in height and 40 cm in width with the intensity of convolution declining upwards (Fig. 3F).
Undulated deformations
Undulate deformation, an indicator of weak compression, is commonly found between two undeformed layers. This type of SSDS can be identified in various structural backgrounds, depositional environments, and lithologies. Moreover, the scale of undulating deformations was measured over a broad range, from several centimeters to meters. Most undulate deformations, showing dimensions up to 80 cm in height and 2 m in width, are observed in the middle part of the Wumishan Formation in the Yixian section. The undulated layers usually formed in the thin gray laminated dolostones between the undeformed underlying and overlying layers (Fig. 3G and 3H).
Stratigraphic context and depositional environment of loopites
Loopites are identified in the lower part of Member I in the Wumishan Formation in the Yixian section (Fig. 2C). Based on the results of observation, these loopites are preserved on multiple bedding surfaces. Moreover, according to the different morphologies, the loopites can be divided into three types: types I, II and III.
The stratigraphic interval preserving type I is the laminites with bright laminations, which are massive to laminated micritic dolostones, and dark laminations, which are algal dolostones (Fig. 4A). From bottom to top, the morphologies of the laminations change from wavy to horizontal, and the stable and thickly developed laminites show that the hydrodynamic force gradually weakens, which demonstrates the depositional features of the lower subtidal zone. Type I loopite develops between two horizontal layers of laminites and is ~ 5 cm thick (Fig. 4B).
Type II is preserved in a 10 cm thick gray dolostone interval with very thin and intensive laminations (Fig. 4C). The thickness of each lamina is thinner than type I, and the overall hydrodynamic force is weaker, indicating the sedimentary environment of the lower part in the lower subtidal zone.
The stratigraphic interval of type III is composed of gray to light-gray wavy-bedded micritic dolostones, which are above the grayish massive grain dolostone (Fig. 4D, E). The major types of grains are round punctate thrombolites and tabular thrombolites with blocky mesoclots (Fig. 4F). Moreover, the distribution of round punctate thrombolites was disturbed downwards, stratified and distributed upwards. In addition, the same characteristics of wavy-bedded deposition were observed on other two outcrops separated by a few meters, and intense SSDS intervals were identified under the wavy beds (Fig. 4G, J). Comprehensively analyzing, the wavy feature means a stronger hydrodynamic force; hence, type III is deposited in the upper part of the lower subtidal zone, and the intervals containing type III show a weaker hydrodynamic force from bottom to top.
Morphological description of loopites
The loopites are present along the long axis in the cross-sectional view, so the annular laminations can be clearly exhibited. Type I (3.5–12.5 cm in length and 0.6–2 cm in height) developed in the laminites and appear alone or in discontinuous chain shape (Fig. 4A, B). The core of type I is black strip-shaped algal micritic dolostone, and the annulate laminations are composed of thick layers of continuous dark-gray algal dolostones with discontinuous white micritic dolostones, which show the blurry morphology of a cross-sectional pseudoconcentric cylinder.
Type II (2.5–5 cm long and 1–2 cm wide) usually appears alone with a poor sectional cylindrical shape; meanwhile, the top-covered laminations exhibit the obvious features of pinching and shrinking on the ends of loopites (Fig. 4C). In general, the core is relatively small, and the laminations above the core are more curved than those below.
Type III (11.5–27.5 cm long and 5–12 cm wide) appear alone or stacked with each other and are not preserved in the chain shape. The annulated laminations of type III clearly display features of interbedding of dark and light color layers and good curvature on the ends. The core is a long strip of dark-gray algal micritic dolostones 3.5–25 cm in length and 2–5 mm in height (Fig. 4E, I, J). Since the largest dimension of type III is incomplete in the section, only half of the part is visible. Thus, the actual length of the whole loopite should be longer.
According to the stratigraphic context, the loopites deposited in a relatively weak hydrodynamic environment lacking the impacts of tectonics. However, considering the stratigraphic interval and morphology, the sedimentary environment of each loopite type is virtually different. Type III deposited in the relatively strongest hydrodynamic environment with the largest size among the three types. Type II is the smallest type with the weakest hydrodynamic force, and type I is the moderate type. Thus, the different hydrodynamic environment determined the different types of loopites.
Discussion
Triggering mechanism of SSDS
According to the results of comprehensive observations, the major triggering mechanism of SSDS in the Wumishan Formation is earthquake. The mound-and-sag structures occurred during the episode of deposition with unconsolidated sediments and was triggered by earthquake-induced transtensional and compressional shear stress (Rossetti and Goes 2000; He et al. 2021). When an earthquake occurs, the vibration could make the overlying liquefied sediments separate from the parent rock and form balls or pillows floating in the underlying less dense sediments (Ezquerro et al. 2015). The unique load structure is a driving force system related to gravitational instability (Zhong, et al. 2017). But because of the differences in densities, it was impossible to form load structures under geostatic pressure. Only in the strong earthquake-triggered situation did the underlying layers have stronger liquefaction than the overlying layers, which could make the lower density layers sink down to form that load structures (Qiao, et al. 2012).
The parent rocks of liquefied veins are micritic dolostone layers that contain pore water, and dissolved air escapes in the lower pressure direction under vibration triggered by earthquakes (He and Qiao 2015). In the study area, the appearance of plate-spine breccias often accompanies convolute beddings because both were formed by compression whose triggering mechanism was interpreted as intense seismic activity (Bhattacharya and Bandyopadhyay 1998; Rossetti 1999; Qiao and Gao 2007; Li et al. 2008; El Taki and Pratt 2012). Moreover, the undulation degree of undulate deformation also depends on the strength of compression caused by earthquakes (van Loon and Su 2013).
The relationship between SSDS and microbial mats
Based on the results of observations, earthquake-induced mound-and-sag structures usually have a relatively large scale, and their features are not necessarily associated with microbial mats. However, it is obvious that the pillow structures can be presented by the deformation of microbial mats (Fig. 3B). Furthermore, the curvature and curl of the soft microbial mats can also increase and lead to soft-sediment deformation. In general, microbial mats are not necessary for the formation of load structures because as long as a density difference exists, gravity or earthquakes can induce deformation. However, if microbial mat intervals appear, they may produce different densities much easier than non-biofilm intervals. Thus, the existence of microbial mats indicates positive effects on the formation of load structures. Similarly, it seems that the formation of vein-type structures is not related to the microbial mats because the veins are rooted in the carbonate particle layers (Fig. 3D). However, because of the trapping and binding from the growth of microbial mats, carbonate particles can be cohered and deposited to form heterogeneous laminations (Samanta et al. 2011). Therefore, although the microbial mats are not the direct triggering mechanism of forming liquefied veins, they contribute to producing the material basis of the liquefied veins.
Apparently, compared with the above types of SSDS, the relationship between plate-spine breccias and microbial mats becomes tighter, and it can be interpreted that the initial forms of the breccias are laminites with horizontal laminations, which are consolidated or unconsolidated microbial mats (Su and Sun 2012). This is why plate-spine breccias cannot be found in massive or homogeneous rocks. As a result, microbial mat-related laminites can be an indispensable precondition for plate-spine breccias. The most common SSDS in the Wumishan Formation are various convolute beddings and undulate deformations, which are formed by the deformations of initially horizontal laminations that are formed from alternating deposited microbial mats and carbonate particles. Hence, even if the blackish beddings and the gray laminations had been convoluted or undulated (Fig. 3F, G, H), it is obvious that the original form of these convolute beddings was flat multilayered microbial mats. This phenomenon is ascribed to the fact that microbial mats are the only biological agents that form laminar deposits in Mesoproterozoic carbonates. Consequently, earthquakes are the triggering mechanism, but the existence of microbial mats is a prerequisite for the two types of SSDS. The microbial mats are not only the material basis for forming the convolute beddings and undulate deformations but also the convolute and undulate microbial mats are precisely the SSDS themselves. Evidently, the major functions of microbial mats for SSDS are producing the material basis or the proxy to exhibit SSDS, not as the major triggering mechanism. Indeed, because of the close relationship between SSDS and microbial mats in the Wumishan Formation, it is easy to confuse our first found loopites with loop beddings.
Possible origin of the loopites
Therefore, we interpret the unusual loopites as the previously undescribed MISS, mainly based on the following observations and analyses: (1) The laminations of loopites display distinct interbedding of dark and light color layers, which is the typical feature formed by the growth of microbial mats. (2) Every loopite contains a core, and the types of the cores can be rock debris (Fig. 5C) or strip-shaped algal dolostones (Fig. 5A). In addition, the number of top-covered layers of the core is greater than the number of underlying layers, which demonstrates the growth of microbial mats (Fig. 5C). (3) Even though the cores of the loopites are not circular, the wrapping laminations on the edges demonstrate good roundness and curvature, which is an obvious feature of sedimentary structure. The loop beddings or boudinages formed by the compressive or tensile stress generated by tectonic movement do not have this feature. (4) The laminations are growing around the core layer after layer. The most direct evidence is that the formation stage of the loopites is observed on the type I outcrop. In Fig. 5B, a single strip-shaped black-gray algal dolostone (35 cm in length and 1.5 cm in height) becomes the core of a type I in the interval of laminites. Then, the outer layer with the same lithology wraps the core from top to bottom. The left and right ends exhibit a good but incomplete arc shape, and the left curves better than the right. The bottom surface of the core presents the features of light-gray microbial dolostones, indicating that the microbes were aggregating along the bottom to form new microbial mats. Furthermore, due to the influence of the loopite, the upper laminations are bent to cover the loopite, and the degree of curvature on the left side is higher than that on the right, which has the same trend as the curvature of the two ends of the loopites. In addition, the lower laminations below the loopite maintain a horizontal shape without deformation. This further illustrates that loopite is the structure caused by microbial activity during deposition, and the growth rate of microbial mats above the core is larger than that below the core.
Compared with other special structures, such as lenticular-flaser structures, pseudonodules, and various types of microbialites in the Proterozoic strata (Song and Gao 1985; Bhattacharya and Bandyopadhyay 1998; Guo, et al. 2013; Rasmussen, et al. 2009), it is difficult to classify the loopites into one certain type due to their unique morphologies. In addition, concentric laminae are usually deemed to have formed by related microbial activities in a high hydrodynamic environment (Pufahl et al. 2013; Diaz et al. 2017). However, we strongly agree that the possible origin of the loopites is related to the growth of microbial mats with relatively weak hydrodynamic forces.
In Fig. 6, in the early formation stage of the loopite, a microhighland appeared on the previously formed flat and broad microbial mats. The origin of the microhighland is due to some debris, such as rock debris and fragments of microbial mats, being brought and dropped on the flat microbial mats by the tidal current from the upper part of the tidal flat (Fig. 6-Stage B). Alternatively, the carbonate sedimentation rate increased, which caused the carbonate to be deposited slightly thicker here and changed the original microtopography (Fig. 6-Stage B1). Through this study, we found that the two possible origins of the microhighland have different effects on the formation and morphologies of the loopites. Therefore, we will discuss them separately.
First, when the microhighland was formed by a dropped rock debris, the microbial mats under the debris sank slightly. Because of this highland, the photosynthesis intensity and deposition rate here are both greater than those in other flat areas. Hence, cyanobacteria are more prone to aggregate together at this spot to form a new microbial mat and then cover the top of the rock debris. This process repeats until the thickness of the top-covered microbial mats reaches a certain scale, which causes the rock debris to sink downwards due to gravity. Because of the above pressure, the microbial mats under the rock debris start to sag and bend (Fig. 6-Stage C). Furthermore, the separately top-covered and underlying microbial mats begin to connect and polymerize to each other due to adhesion and adsorption (Fig. 6-Stage D) and then wrap the rock debris to form the loopite (Fig. 6-Stage E). Notably, the loopites with debris cores are distinguished by the thickness of single underlaid annulated laminations being greater than that of top-covered laminations because the formation of underlaid laminations mainly depends on adsorption due to pressure; conversely, the total thickness of the top-covered laminations formed by normal sedimentation of microbial mats is larger than that of the underlaid laminations. Consequently, the stratification of the underlying annulated laminations is weaker and more obscure than that of the top-covered laminations. In our case, types II and III both had the same origin as described above.
Second, if the microhighland was formed by the increased carbonate sedimentation rate, the thickness of the carbonate sediments here will be slightly larger than other flat parts. Similarly, the photosynthesis intensity and deposition rate are higher in this high spot; therefore, cyanobacteria will gather here first to form a new microbial mat that has the same size as the highland (Fig. 6-Stage C1). As the process was repeated, an increasing number of new microbial mats covered the highland with increasingly larger sizes. Furthermore, the larger microbial mats that cover the initially formed microbial mat began to bend downwards because of currents and gravity, and then the initially formed microbial mat became the core and was wrapped by the top-covered mats (Fig. 6-Stage D1). However, the poorly stratified carbonate sediments below the core are too thick to bend; therefore, the underlying microbial mats are difficult to polymerize with the top-covered mats via adhesion or adsorption. Simply, the annulated laminations of this type of loopite are mainly formed by the top-covered microbial mats wrapping downwards and assisted by the adsorbed microbes on the bottom of the core (Fig. 6-Stage E1). Obviously, type I in our study relies on the formation described above with obscure laminations and smaller thicknesses.
Possible environmental controls on the loopites
The Wumishan Formation was deposited in the half-graben basin of the Yanliao aulacogen (Chen 1983; He et al. 2000), which was formed by the extensional rifting of the North China Block during 1.8–1.6 Ga (Cao 2002; Peng et al. 2004) because of the breakup of the Columbia supercontinent (Zhao et al. 2003; 2004; 2011). A series of NE- and NW-striking syngenetic faults developed in the Yanliao aulacogen (Qiao and Gao 2007), which were generated by intraplate rifting and induced strong earthquakes. The ample records of earthquake-induced SSDS in the Wumishan Formation in the Yixian section, which is located near the major NE syngenetic Lingyuan–Miyun fault (Zhang et al. 2007), verify that the development and distribution of SSDS in the Wumishan Formation were controlled by the axial faults in the Yanliao aulacogen. Based on our detailed analyses of the outcrops, SSDS can be identified in all members of the Wumishan Formation in the Yixian section; however, the overall tendency shows that the types and frequencies of SSDS decrease from Members I–IV, which may reveal that during the depositional period of the Wumishan Formation, the effect of paleoearthquakes became weaker, and the Yanliao aulacogen entered a relatively stable stage from a strongly extensional stage.
The deposition of the Gaoyuzhuang Formation (1.6 Ga?–1.54 Ga?) (Tang et al. 2022) is the response of the first massive transgression of the Jixianian, representing the main deposits of the Yanliao aulacogen entering the sedimentary stage of the epicontinental sea (Huang et al. 2001) until ~ 1.4 Ga (Pan et al. 2013), which further demonstrates that the North China Block entered the relatively stable stage from the cracking of the Columbia supercontinent (Zhang 2004). Consequently, under such a depositional background, a transgression occurred in the early deposition of the Wumishan Formation to deposit thick intervals of laminites, and loopites are identified in such laminites that contain densely packed interbedding of dark and light color laminations (Fig. 4A–D), which are composed of abundant microbial remains in the dark laminations, suggesting a biogenic origin (Fig. 5A–C). The dark laminites in the Wumishan Formation in the Yesanpo section are considered the products of subtidal lagoons and contain no current- or wave-influenced sedimentary structures (Tang et al. 2014). However, this kind of laminite dominates Member I of the Wumishan Formation in the Yixian section, implying a different sedimentary environment.
In terms of dominance, the laminites occur in the lower subtidal facies, and from the lower to upper part of the lower subtidal zone, their laminations change from horizontal to wavy forms (Fig. 4A–D), which provides evidence that hydrodynamics are an important control on the development of laminites. In the same way, with the change in hydrodynamics, the morphologies and sizes of loopites are altered. Due to the initial transgression of the Wumishan Formation, the types of sediments change from ooids (Fig. 7A–C) to tabular thrombolites (blocky to round punctate mesoclots) (Fig. 7D) to laminites (wavy to horizontal). This clear tendency suggests that the depositional environment changes from a lower intertidal to a lower subtidal zone with continuously weakened hydrodynamic forces, which are controlled by rising sea level in a broad environment.
Apparently, three different types of loopites occur in three different types of laminites (Fig. 4A, C, D), and the common prerequisite for forming the loopites is abundant microbial mats (Fig. 7E), which are derived from the increase in Mesoproterozoic microbial abundance (Riding 2006). However, calcified cyanobacteria were barely found in the laminations of loopites, which possibly demonstrates that p (CO2) is much larger than 10 PAL (present atmosphere level) (Riding 2011). In addition, the precipitation of fibrous aragonite was identified in the laminations of laminites and loopites (Fig. 7F), which may indicate that the carbonate saturation was much higher than that in modern oceans and that the bacterial sulfate reduction (BSR) played an important role in consuming organic matter and sulfate to produce bicarbonate to ensure precipitation, which means that loopites were deposited in an anoxic and carbonate-supersaturated environment with a relatively high microbial biomass (Grotzinger and Kasting 1993; Grotzinger and Knoll 1999; Brocks et al. 2005; Tang et al., 2013c). Thus, under possible similar environmental conditions, the advent of loopites is controlled by the activities of the microbial community, which can be influenced by illumination and microtopography, and their morphologies and sizes are controlled by hydrodynamics. Due to phototropism, microbes preferentially grow on the microhighlands to obtain stronger illumination to increase the growth rate, which would produce thicker laminations (Diehl 2002; Tang et al. 2014), reflecting that the environment influences the activities of the microbial community and the sensitivity of the microbial community to changes in the environment. Moreover, when the hydrodynamics become stronger, forming the annular stromatolitic structures of loopites is the response and reactivity of microbes against and slows down the water flow to maintain the proper weak hydrodynamic environment for their growth. Thus, as the hydrodynamics become increasingly stronger, the sizes become increasingly larger (Fig. 8). As a result, type II develops in the deepest and weakest hydrodynamic environment and contains the thinnest laminations and smallest size. Conversely, type III forms the largest size because of the shallowest water depth and strongest hydrodynamics (Fig. 8). In addition, this is why only the laminations of the loopites retain the horizontal shape along the long axis in the wavy laminites (Fig. 4D and 4G). Thus, the loopites may indicate a relatively weak but frequently changing hydrodynamic environment with relatively high microbial biomass.
Conclusion
Seven different types of earthquake-induced SSDS, which contain obvious tendencies suggesting that the types and frequencies decrease from Members I–IV, have been identified in a well-preserved outcrop of the Wumishan Formation in the Yixian area, which is located near the major NE syngenetic Mesoproterozoic Lingyuan–Miyun fault. The location and the tendency may indicate that the development and distribution of SSDS were controlled by the axial faults in the Yanliao aulacogen; however, the effect of paleoearthquakes became weaker, and the Yanliao aulacogen entered a relatively stable stage from a strongly extensional stage during the depositional period of the Wumishan Formation.
Most SSDS have been identified to be associated with microbial mats. The relationship between SSDS and microbial mats can be interpreted as the microbial mats can provide a material basis and be a proxy for SSDS, but their main function is to form the MISS and to deposit microbialites during their growth. Thus, the biogenic-origin laminites with interbedding of dark and light color laminations were deposited in the lower subtidal facies and dominated Member I of the Wumishan Formation. Moreover, three different types of loopites are identified in three different types of laminites; meanwhile, abundant microbial mats, a lack of calcified cyanobacteria and the precipitation of fibrous aragonite are found in the laminites, demonstrating that the problematic loopites are formed in an anoxic and carbonate-supersaturated paleoenvironment with a relatively high microbial biomass.
Because of the essential difference in the formation, the first found problematic loopites (2.5–27.5 cm in length and 0.6–12 cm in height) from the Mesoproterozoic Wumishan Formation are not loop beddings but belong to examples of a previously undescribed MISS that formed by the growth and wrapping of microbial mats. Based on our reconstructive formation processes and sedimentary model, the formation of loopites is controlled by illumination, microtopography and hydrodynamics. To produce thicker laminations, the microbes will grow on the higher microtopography preferentially to obtain stronger illumination. Meanwhile, to maintain the proper weak hydrodynamic environment for their growth, the microbial mats will grow on the higher microtopography to form the annular stromatolitic structures of loopites to protect against and slow down the stronger hydrodynamics. In addition, as the hydrodynamics become increasingly stronger, the sizes of loopites become increasingly larger. Thus, the significance of the discovery of loopites is not only to provide a new type of MISS, but also to reflect how the depositional environment influences the activities of the microbial community and the sensitivity of the microbial community to changes in the environment. The presence of loopites may suggest a new and pure sedimentary growth mechanism of the microbial mats to form annulate structures in a relatively weak but frequently changing hydrodynamic environment in the Mesoproterozoic period.
The annulate and laminated structures attracted the attention of the global academic community. The proposed genetic model of the loopite in this study provides another new possibility for the formation of annulate and laminated structures. Although the loopite is currently first reported in North China, it is widely distributed in the Mesoproterozoic in North China. Therefore, we believe that scholars around the world will gradually pay attention to this structure and report on it. We look forward to the comparability of loopites in different sites of the world, which can make them a signature structure in the Mesoproterozoic sedimentary environment.
Data availability
All relevant data are within the paper.
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Acknowledgements
The authors wish to thank the editor LaMoreaux and two anonymous reviewers for their valuable and helpful comments and suggestions. The authors also thank Pu Wan, Yingzhuo Cao, Ke Zhang and Ruiyu Wang for assistance in the field. This work was co-supported by the Class A Strategic Priority Research Program of the Chinese Academy of Science (No. XDA14010201) and the National Key Research and Development Programs of China (Grant No. 2018YFC0604304).
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Lu, K., Bao, Z. & Li, J. Soft-sediment deformation structures or microbially induced sedimentary structures: the description and possible origin of the "loopites" in the Mesoproterozoic Wumishan Formation, North China. Carbonates Evaporites 39, 33 (2024). https://doi.org/10.1007/s13146-024-00944-7
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DOI: https://doi.org/10.1007/s13146-024-00944-7