Abstract
Using observations and descriptions of drilling cores, image logging, microscopic section, argon ion polishing field emission scanning electron microscopy, X-ray diffraction, and whole-rock trace element analysis, the study of shale reservoir diagenesis and space types in the Fengcheng Formation of the Mahu Sag was conducted. Considering the trace element contents and their ratios (Sr/Ba, V/Ni, Th/U, V/(V + Ni), U/Mo, and Sr/Cu), the Fengcheng Formation is formed in a dry and hot continental lacustrine basin with a paleoenvironment of saltwater and anoxic/lean oxygen conditions. The shale reservoirs of the Fengcheng Formation with the characteristic of multisource mixed sedimentation include terrigenous clastic, volcaniclastics, and carbonate rocks. Currently, the Fengcheng reservoir of the Mahu Sag is in the middle of diagenetic-stage B. The principal factors for reservoir densification are compaction, dissolution, carbonate mineral cementation, and clay mineral cementation. The Fengcheng Formation develops multiple reservoir storage space types, such as rock fractures, stylolites, and micro–nanoscale pore-throat systems. The macroreservoir space types include tectonic, induced, bedding, and dissolution–expansion fracture types. The microreservoir space types include microfractures, stylolites, and micro–nanoscale pore throats. The research showed that the Fengcheng Formation has tectonic fracture-pore systems (tectonic fracture-type reservoirs) and stylolite-matrix pore-tectonic microfracture systems (shale oil reservoirs), forming the shale oil preponderant charging channel network. Reservoir space type and its spatial distribution are the principal factors for shale oil accumulation of the Fengcheng Formation in the Mahu Sag.
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Introduction
Great successes in the Bakken shale area in the Williston Basin (Kuhn et al. 2012; Pollastro et al. 2012; Angster and Sarg 2013), the Eagle Ford shale area in the western Gulf of Mexico Basin (Hentz et al. 2014; French et al. 2019; Fairbanks et al. 2016), the Wolfcamp Formation in the Permian Basin (Ojha et al. 2018), the Niobara Formation in the Denver Basin (Han et al. 2019), and the Paleogene Green River shale area in the Green River Basin (Burton et al. 2014; Sarg et al. 2013; Burnham 2017) have changed the oil and gas supply pattern of North America, causing a worldwide upsurge in shale oil and gas exploration and exploitation. Compared with the geological characteristics of North American shale oil, with an open-sea deposition, single lithology, source-reservoir separation, and a concentrated distribution of sweet spots, Chinese shale oil has the characteristics of terrestrial multisource mixed sedimentation, source-reservoir transition, and scattered sweet spots. Affected by high-frequency climate change, continental shale reservoirs with characteristics of frequent facies change, a complex lithology, and strong heterogeneity have diverse sedimentary environments. Shale oil in China is mainly distributed in continental lacustrine basins as follows: Cretaceous of the Songliao Basin (Cao et al. 2017), Paleogene of the Bohai Bay Basin (eastern China) (Chao et al. 2017; Chen et al. 2017; Lu et al. 2015), Triassic of the Ordos Basin (Cui et al. 2019; Lai et al. 2016; Sun et al. 2020; Jiang et al. 2017; Yao et al. 2009; Wei et al. 2019), Jurassic of the Sichuan Basin (central China) (Li et al. 2018; Wang et al. 2018), and Permian of the Junggar Basin (western China) (Zhang et al. 2019a, b, c; Luo et al. 2018).
Shale oil originally only referred to oil related to oil shale. Later, as the exploration degree of unconventional oil and gas resources and related research improved, many institutions and scholars expanded the definition and connotation of shale oil and formed the following mainstream understanding. (1) Shale oil refers to petroleum resources rich in organic shale. Shale formation is a hydrocarbon source rock and a reservoir that is more compact than sandstone and carbonate tight oil reservoirs (Zou et al. 2019a, b). (2) The concept of shale oil is equivalent to tight oil, typically referring to petroleum resources stored in tight oil-bearing formations having low porosity and permeability (Clarkson and Pedemen 2011; Zhang et al. 2019a, b, c). (3) Shale oil refers to oil and gas resources in the shale oil and gas system, including organic-rich mudstone and shale as well as the interbedded and adjacent organic-poor reservoirs (Jarvie 2012; EIA 2013; Bowker 2007; Blaizot 2017). In this study, shale oil refers to petroleum resources accumulated in the hydrocarbon source-rock strata or shale system. Its reservoir thickness is less than 5 m, layer thickness ratio is less than 50%, and overburden matrix permeability is less than 0.1 mD (Nelson et al. 2011). Horizontal drilling and multistage-fracturing technology must be used to realize economic exploitation. Shale pores are mainly nanopores (Zhang et al. 2019a, b, c). The pore throats of marine shale are distributed in the range of 0.005–0.05 μm. The radius of some pore throats is as high as 0.1 μm, including the radius of intergranular, intragranular, and organic pores (Yan et al. 2018; Guo et al. 2018; Fu et al. 2015). The main diageneses of shale reservoirs are compaction, cementation, dissolution, and metasomatism (Dowey and Taylor 2020; Taylor and Macquaker 2014; Milliken et al. 2012). Compaction is critical in the densification of shale reservoirs, and cementation has a certain destructive effect on reservoirs (Petrash et al. 2016).
The Fengcheng Formation of the Mahu Sag, Junggar Basin, is the oldest alkaline lake deposit discovered in China, containing rich unconventional oil and gas resources. Earlier studies have proposed that the Fengcheng Formation is the main source-rock series that is extensively distributed in the Mahu Sag. Deepening geological theory knowledge and progress in exploration and development technology has confirmed that the Fengcheng Formation of the Mahu Sag is a new field for shale oil exploration in a continental saline lacustrine basin with a rich resource potential. It is critical to understand the control factors of alkaline lake-type shale in the Fengcheng Formation. Unfortunately, the control factors have rarely been studied. Current research on the Fengcheng Formation of the Mahu Sag mainly focuses on the sedimentary environment analysis of the source rock (Cao et al. 2015, 2020; Wang et al. 2020; Lu et al. 2015), organic geochemical characteristics (Tao et al. 2016; Yu et al. 2018), thermal evolution stage, genesis of dolomitic rocks (Zhu et al. 2016a, b), and hydrocarbon-generation potential (Zhang et al. 2018). However, diagenesis of various lithologies deposited in the saline lacustrine environment of the Fengcheng Formation and Mahu Sag has not been studied in detail. Furthermore, there is a lack of systematic research on the petrological characteristics, diagenetic-stage division, reservoir space types, and genetic mechanism analysis of shale reservoirs. In this study, the mineral composition, rock classification, nomenclature, sedimentary environment, diagenetic evolution sequence, and multiscale reservoir space types of the alkaline lake-type shale reservoir of the Fengcheng Formation in the Mahu Sag are studied. The combination model for reservoir space of shale oil is established.
Geological setting
The Mahu Sag is in the southeast of the western uplift of the Junggar Basin. Its paleogeomorphic features are asymmetrical pan-shaped sags with steep west and gentle east east–west zonations and north–south segments, including a central depression, volcanic highlands, structural slope breaks, and other geomorphological units. The Mahu Sag is adjacent to the Wuxia fault zone in the west, covering approximately 5000 km2. The Fengnan area is in the Mabei slope area of the Mahu Sag. The Mesozoic has three sets of oil-bearing combinations, namely, the Baikouquan Formation of the Triassic system, the Lower Wuerhe Formation of the Upper Permian series, and the Fengcheng Formation of the Lower Permian series. The Fengnan area is bounded by the Wuxia fault zone in the north, the Baiwu fault zone in the west, and the Mahu Sag in the southeast, covering approximately 600 km2 (Fig. 1). According to the difference in the structural characteristics, the Fengnan area can be divided into three subtectonic units from the west to the east, namely, the Wuxia thrust belt, the central fault-fold area, the slope belt, and the eastern uplift zone. The Fengcheng Formation of Lower Permian in the Junggar Basin is a semideep–deep lacustrine sedimentary environment with three types of reservoirs of terrigenous fan delta glutenite, volcanic rocks, and lacustrine fine-grained dolomite (Li et al. 2021). During the sedimentation period of the Fengcheng Formation, the transgression period is from the late stage of the first member (P1F1) to the early stage of the second member (P1F2) and it then gradually regresses, forming the Fengcheng Formation’s wide-covered high-quality source rock (Zhang et al. 2018).
Under this sedimentary background, the Fengcheng Formation has developed a lithological sequence from organic-rich shales to tight volcanic rocks, forming two types of unconventional oil and gas reservoirs (Hu et al. 2015). (1) The third and second members of the Fengcheng Formation are typical shale reservoirs with integrated sources and reservoirs (P1F3 and P1F2). (2) The first member of the Fengcheng Formation (P1F1) is a tight volcanic-rock reservoir of adjacent hydrocarbon source rocks. The dolomitic reservoirs of the third and second members contain abundant shale oil resources. Their lateral distribution is stable and widely developed, comprising four fine-grained sedimentary types, such as argillaceous dolomite, dolomitic mudstone, dolomitic siltstone, and dolomitic tuff. Vertically, lacustrine dolomitic reservoirs and dark-mud shale are interbedded and these reservoirs are tight and contain oil in a large area. The Fengcheng reservoirs’ porosity in the western slope of the Mahu Sag is 1–13%, with an average of 2.89%, and its permeability is less than 0.1 mD, exhibiting overall characteristics of low porosity and compactness. The shale oil is characterized by low crude-oil density (0.82–0.87 g/cm3), a low freezing point (− 14.8–5 °C), and high crude-oil viscosity (2.75–770.4 mPa•s at 50 °C). It is estimated that the current shale oil resources in the western slope zone of the Mahu Sag amount to 420 million tons, which is critical for the Junggar Basin to increase production and reserves in future.
Method experiment
From the main intervals of the P1F2 and P1F3 shale reservoirs, 100 core samples were collected from 21 wells. The core sample lithology includes terrestrial clastic rocks, carbonates, pyroclastic rocks, salt rocks, and mixed rocks. The samples were analyzed using techniques such as thin section (TS), X-ray fluorescence spectroscopy (XRF), X-ray diffraction (XRD), and field emission scanning electron microscopy (FE-SEM). In total, 220 TSs were analyzed. The TSs were impregnated with epoxy to microscopically observe sedimentary pore structures and diagenesis. Casting TSs were observed using petrographic microscopes to distinguish the pore genesis and types. The trace element, whole rocks, and clay mineral contents of the shale samples were identified at the China National Petroleum Corporation (CNPC) in Hangzhou. SEM and FE-SEM were conducted at the Xinjiang laboratory of petroleum resources in conglomerate, at the Xinjiang Oilfield Company, PetroChina.
Trace element analysis
XRF analysis of trace elements in rock samples was performed using the compression molding method. The instrument was Panalytical Axios, and the implementation standard was Silicate Rock Chemical Analysis Method Part 28 to determine 16 major and minor components (GB/T 14,506.28, 2010). The temperature in the laboratory was 21 °C and humidity 23%.
XRD
The whole-rock and clay mineral contents of the core samples were detected using TTR XRD produced by the Rigaku Motor Company in Japan, following SY/T5163-2010. Whole-rock mineral analysis used 200 mesh powder samples, and each mineral’s mass percentage was calculated using an analysis software and referred to the K value of international standard samples. The relative mineral percentage was measured semiquantitatively. The temperature in the laboratory was 24 °C with 35% humidity.
FE-SEM
The FEI Quanta200F type SEM and Apreo S type FE-SEM were used for observation. Before the observation, the smoothed sample’s surface was polished with argon ion and the rock sample was preprocessed following the SEM analysis standard (SY/T5162-2014) of the rock sample issued by the CNPC. Before sample processing, remove residual oil. The temperature in the laboratory was 25 °C with 35% humidity.
Results
Mineral composition content and rock classification nomenclature
The Fengcheng Formation in the Mahu Sag is the oldest alkaline lacustrine deposition in China. It developed a suite of transitional mixed rocks (terrestrial clastic rocks, endogenous chemical sedimentary rocks, and volcaniclastics materials), and the mineral types in this formation are diverse (Fig. 2). Terrestrial clastic rocks are distributed in the fan delta sedimentary area at the edge of the lake basin, mainly composed of conglomerates, fine-grained sand, and siltstones. The mineral components are mainly feldspar and quartz, and the content of clay minerals is less (Fig. 3a, b). Quartz and feldspar grains are angular and subangular. Detrital particles in the sandstone are well sorted and highly rounded. The feldspar and rock debris contents are high, and the interstitial material is mainly argillaceous, with occasional calcareous cementation. Microbedding planes are developed in the mud shale and are mostly filled with organic matter in the later stage. Carbonates are widely distributed in the shallow-shore and semideep lacustrine sedimentary areas comprising endogenous calcite, dolomite, ankerite, ferrocalcite, and other minerals (Fig. 3c–f). Significant differences exist in the grain size and crystal shape of dolomite minerals, including micrite, powder, and fine and medium crystals. The micritic and silt-crystalline dolomites are uniformly distributed in the rock, and the local occurrence is laminated. Fine- and intermediate-grained dolomites are enriched and distributed along fractures and microbedding planes.
Pyroclastic rocks have porous structures and are rich in volcanic materials such as crystal fragments and glass shards (Fig. 3g, h). The crystalline shape is angular and medium and has poor sorting, and the mineral composition is mainly quartz, feldspar with a small amount of biotite, local silicification, and chloritization phenomenon. Salt rocks mainly include alkaline minerals (sodium carbonate and bicarbonate), Na–Ca–Mg-type carbonate (shortite and northupite), and reedmergnerite (Fig. 3i–n). Sodium carbonate is mostly of medium-coarse crystal structure, and the aggregate is mostly intersected plate columnar with low hardness. Trona minerals have crystal optical characteristics of a colorless, fibrous crystal shape; negative low protrusion; and a senior white interference color. Most mineral aggregates of shortite are plate like or short columns. They are for clarity or light yellow, have a negative low protrusion, and appear red after being dyed by potassium ferricyanide and alizarin red mixture. The reedmergnerite aggregates are gray or light gray, and the morphologies are dense banded or lenticular. Mixed rocks are distributed in the shoreline shallow lake sedimentary area, which is dominated by mixed accumulation, and the laminated structure is relatively developed. Sedimentary structures mainly include compact massive, horizontal bedding, interlaced bedding, and algae laminated (Fig. 3o–r).
The Fengcheng Formation, comprising complex and diverse mineral types, has a massive resource potential, with the appearance of high alkaline and accessory mineral contents. The existing classification and nomenclature standards make it challenging to reveal rock characteristics of the alkaline lacustrine shale formation. Many problems exist for the classification and nomenclature of organic-rich shale in China and abroad, including chaotic nomination, abusive, and scientifically illogical. Moreover, the classification and nomenclature of alkaline lacustrine shale formation have not been studied systematically (Lazar et al. 2015; Camp et al. 2016). Foreign experts have considered felsic, clay, and carbonate minerals as three endmembers for the classification of organic-rich shale (Gamero-Diaz et al. 2013; Xiong et al. 2019).
Based on the literature research and analysis as well as geological characteristics of the alkaline mineral composition and sedimentary structure in the core scale, this study proposes a new method for classifying rock types of alkaline lacustrine shale formations. Felsic, carbonate, pyroclastic, alkaline minerals, and sedimentary structures were used as the classification endmembers of alkaline lacustrine shale formations. A ternary diagram of terrestrial detrital, carbonate particles, and pyroclastic rocks was established. Two critical parameters—alkaline mineral component content and sedimentary structure in core scales—were introduced into a petrological triangle classification system of shale formations. Based on the 50% content of main rock mineral components such as felsic, carbonate, tuff, and alkaline minerals, the basic name of the Fengcheng Formation was determined. The Fengcheng Formation reservoirs of alkaline lakes were divided into (I) terrestrial clastic rocks, (II) carbonates, (III) pyroclastic rocks, and (V) salt rocks. If the mineral components of felsic, carbonates, tuff, and alkaline minerals were all less than 50%, they were named mixed rocks (IV).
According to the mineral composition (25–50%), rock names could be further subdivided. Terrestrial clastic rocks were subdivided into dolomitic/calcareous and tuffaceous sandstone. Carbonate rocks could be subdivided into tuffaceous dolomite/limestone and sandy dolomite/limestone. Pyroclastic rock could be subdivided into sandy and dolomitic/lime tuff. Salt rocks (V) of the Fengcheng Formation were composed of Na-type carbonates, Na–Ca–Mg type carbonates, reedmergnerite, and their accessory minerals. Based on the basic name of the rock, the relative content of alkaline minerals (Na-type carbonates, Na–Ca–Mg type carbonates, reedmergnerite, and their accessory minerals are more than 50%) was applied to finely determine rock names, such as sodium carbonate-bearing dolomitic sandstone, sandy dolomite-containing reedmergnerite, and dolomitic tuff-containing shortite. Finally, the rock sedimentary structure was applied to the nomenclature of the Fengcheng Formation, such as a compact, massive structure; siliceous reedmergnerite-bearing dolomitic sandstone; horizontal grain-layered northupite-bearing sandy dolomite; and shale-structure dolomite (Fig. 4).
Analysis of sedimentary environment
We took the Sr, Sr/Ba, V/Ni, Th/U, V/(V + Ni), U/Mo, and Sr/CU values as geochemical indicators to analyze the water medium conditions and paleoclimate in sedimentary environments of the Fengcheng Formation of the Mahu Sag in Fengnan area. The results showed that the ancient water medium in the sedimentary period is in the sedimentary environment of the continental lacustrine basin with high salinity and anoxic (Fig. 5).
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The Sr/Ba ratio, which is the degree of enrichment of trace elements, is closely related to the depositional environment. The Sr/Ba ratio in trace element parameters is typically used as an indicator of marine or terrestrial environments. The chemical properties of strontium and barium are similar, and the Sr/Ba value affects paleosalinity. The change in the Sr/Ba value is sensitive and can be used as a paleosalinity indicator. The larger the ratio is, the higher is the paleosalinity (Fu et al. 2016). The Sr/Ba ratio in freshwater sediments is typically less than 1, whereas in saltwater sediments, it is greater than 1 (Qiu et al. 2015). The results showed that the Sr/Ba ratio of the Fengcheng Formation of the Mahu Sag in Fengnan is 0.09–2.95, with an average value of 1.18, and Fengcheng formation is a salty lacustrine basin sedimentary environment.
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In the Th/U ratio, the U element is enriched in sediments in a strongly reducing environment. The Th is unaffected by the oxidation–reduction environment of the water. The Th/U ratio is 0–2, representing a lean oxygen environment, and it can reach 8 in an oxidizing environment (Wang et al. 2017; Smolarek et al. 2017). The results showed that the Th/U ratio of the Fengcheng Formation of the Mahu Sag in Fengnan is 0.11–12.48, with an average value of 1.2, indicating an anoxic deposition environment.
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In the V/Ni–V/(V + Ni) ratio, V and Ni are elements of the iron group and are highly sensitive to the redox environment; they are also often used as a critical indicator for judging the salinity of deposition media (Makeen et al. 2019; Harris et al. 2004). V is easy to accumulate in an oxidizing environment and conditions with greater acidity, and Ni is easier to accumulate in a reducing environment and conditions with greater alkalinity. Typically, V/Ni is used to analyze a sedimentary environment’s paleosalinity. If the V/Ni value is greater than 3, it is a marine sedimentary environment, and if it is less than 3, it is a continental sedimentary environment. A V/(V + Ni) > 0.84 is a quiet sea phase-reducing environment, a V/(V + Ni) ratio of 0.54–0.84 indicates an anoxic environment, and a V/(V + Ni) ratio of 0.46–0.58 indicates a lean oxygen-deposition environment. The results showed that the V/Ni ratio of the Fengcheng Formation in Fengnan is 0–5.33, with an average value of 1.63, indicating that the sedimentary water body is a continental-reducing sedimentary environment. The V/(V + Ni) ratio of 0–0.84, with an average value of 0.56, indicates a lean oxygen-anaerobic deposition environment.
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Studies have confirmed that the Sr/Cu ratio can effectively reflect changes in the paleoclimate of the lacustrine basin. A Sr/Cu ratio of 1.3–5 represents the temperature and humidity, and a Sr/Cu ratio greater than 5 represents dry and hot conditions. The results showed that the Sr/Cu ratio of the Fengcheng Formation of the Mahu Sag in Fengnan is 1.13–216.22 and the average value is 18.91, indicating that it was formed in dry and hot conditions.
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The U/Mo ratio is a commonly used index to determine changes in the oxidation–reduction conditions of sedimentary water bodies (McManus et al. 2006; Lian et al. 2012). The results showed that the U/Mo ratio of the Fengcheng Formation of the Mahu Sag in Fengnan is 0.01–2.61 and the average value is 0.36. The overall value is too small, indicating an anoxic deposition environment (Table 1).
Types of diageneses
Diagenesis runs through the entire change process—from when sediments are buried and transformed into rocks to metamorphism or uplift to the surface before weathering occurs. During this process, due to changes in the buried depth, ground temperature, and overlying pressure, a series of changes will occur in the original sediments, directly affecting the rock pores’ state and controlling the existence, formation, development, and evolution of pores. The main diagenesis types of the Lower Permian Fengcheng Formation in the Junggar Basin include compaction, pressolution, cementation, and metasomasis. Mechanical compaction is critical in the formation process of tight reservoirs, occurring in the early diagenetic stage, and it has an important impact on the reservoir’s porosity and permeability and causes loss of intergranular pores. The compaction of the Fengcheng Formation in the Mahu Sag is strong. Clastic particles arrange directionally in the lamina, and carbonate particles are lined and concave–convex intergranular contacts.
With the increase in the burial depth, pressolution development increases in the dolomitic rock and pyroclastic reservoir of the Fengcheng Formation, and many parallel or low-angle stylolite structures can be observed. Saw-toothed stylolites are often filled with mudstone or asphalt (Fig. 6a–d). Dissolution improves the tight reservoir space. The Fengcheng Formation’s dissolution mainly occurs in feldspar, rock debris, and carbonate particles, and the pore-expanded dissolution fissure can be seen locally. Feldspar dissolution in the reservoir is common, and the secondary dissolution pores are saturated with oil or filled with ankerite cement of the late diagenetic stage (Fig. 6e–h). TS observations, SEM, and XRD results showed three cement types in the Fengcheng Formation (carbonate, clay mineral, and a small amount of siliceous). Carbonate cement, with the characteristics of widely distributed, multiphased, and diverse genetic types, has a significantly destructive effect on pore formation and evolution. The carbonate cement content of the Fengcheng Formation ranges from 2 to 27%, the calcite content ranges from 1 to 33%, and the ankerite content ranges from 2 to 30%, and carbonate cement has a crystal stock or poikilitic texture.
Three clay mineral cement types are observed in the Fengcheng Formation (chlorite, illite/smectite mixed layers, and illite). Curved flaky chlorite and honeycomb illite/smectite mixed layers are filled in primary residual intergranular and dissolution pores. Illite in is hair and silk shaped (Fig. 6i–l). Pervasive metasomatism occurs in the Fengcheng Formation. Reedmergerite replaced dolomite, shortite, and calcite and carbonate mineral replaced tuffaceous, quartz, and feldspar. Ankerite has a cloudy center and a clean rim structure (Fig. 6m–p).
The terrestrial clastic grains are arranged in obvious directions due to mechanical compaction, and the dissolution pores in the albite and calcite grains are well developed. The carbonate particles are mainly linear and concave–convex in close contact. They are typically formed by late diagenetic metasomatism, such as dolomitization and recrystallization, to form intercrystalline pores in shale reservoirs. The pore sizes are typically less than a few microns. Pyroclastic rocks mainly comprise dissolution pores, and the phenomena of dedolomitization, local silicification, and chloritization are common. Pressure dissolution is widely developed in volcaniclastics reservoirs, and many parallel or low-angle stylolite structures intersect in rock layers can be seen. The secondary recrystallization of salt rocks and alkaline mineral dissolution is also strong, and the phenomenon of dissolution pores and caves can be seen. In the mixed rocks, the reedmergnerite replaced dolomite and carbonate minerals such as shortite and calcite replaced quartz and feldspar particles. Most dolomites in the Fengcheng Formation are metasomatic ankerite.
Multiscale characterization of reservoir space types
The Fengcheng Formation of the Mahu Sag in Fengnan has multiple reservoir space types, such as rock fractures, stylolites, and micro–nanoscale pore-throat systems. Based on the above analysis, research was conducted on the reservoir space types of the Fengcheng Formation shale oil in the Mahu Sag on logging, core, and micropore-throat scales.
The macroreservoir space types of the Fengcheng Formation include tectonic, induced, bedding, and dissolution–expansion fracture types.
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Tectonic fractures: under regional tectonic compression or shear strike-slip conditions, the Fengcheng Formation produced ruptures and deformation, forming high-angle fractures, medium–low-angle fractures, fracture networks, and other complex tectonic fracture systems (Fig. 7a–c). High-angle fractures and fracture networks are mostly filled with calcite, quartz, carbon, and mud. Sheared fractures are relatively straight. The fracture aperture is large, mostly open or partially filled, with good connectivity, long-distance extension, and concentrated distribution in local places (Fig. 7e, f).
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Induced fractures in the Fengnan area are formed by the interaction of well-bore pressure and rock formations during the drilling process. The fractures are often distributed in the middle of the core. Drilling-induced fractures are symmetrically distributed on the formation microimage (FMI) as two black bands parallel to the well axis, have stable orientation, and are extended for a long distance.
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Dissolution–expansion fractures. Tectonic fractures developed in the early stages or zones of secondary dissolution pores have become critical drainage channels for geological dissolution fluids in the later stage and promoted dissolution fracture development. FMIs reveal pinhole-shaped pores formed by dissolution, and the dissolution pore distribution presents a layered structure. The thickness is typically several meters, and resistivity-logging curves commonly feature low values (Fig. 7d). The tectonic dissolution fractures of the Fengcheng Formation are mostly developed in muddy and sandy dolomites, with fracture widths ranging from 1 to 12 mm, either open or partially filled. The dissolution fractures’ shape at the core scale is irregular, and the fracture surfaces are often uneven, with the appearance of dissolution pores and caves (Fig. 7g, j, and k).
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Bedding fractures. Compared with the macrotectonic fractures, the length and scale of bedding fractures in the Fengcheng Formation are smaller and mostly horizontal, increasing the pore network connectivity and promoting secondary pore development. It is also an effective reservoir storage space, favorable for horizontal drainage and shale oil local accumulation (Fig. 7h).
The microreservoir space types of the Fengcheng Formation include microfractures and stylolites and micro–nanoscale pore throats.
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TS and SEM revealed that the Fengcheng Formation developed two types of microreservoir space types (transgranular microfractures and pressure-solution stylolites) (Fig. 7i, m, and n). The transgranular microfractures are tectonic, mostly developed in brittle rocks, such as dolomite and dolomitic siltstone. They often cut through multiple mineral particles, and the fracture width ranges from 20 to 80 μm, with a dendritic shape and a long-distance extension. Microscopically, pressure-dissolution fracture surfaces are mostly curved or irregular with a short extension distance. They mostly connect the dissolution and intercrystalline pores of mineral particles, forming a three-dimensional pore-fracture drainage system for shale oil. The stylolites in the Fengcheng Formation often experienced multistage dissolution or were filled with minerals such as dolomite and ankerite.
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The micro–nanoreservoir space of the Fengcheng reservoirs in the Mahu Sag mostly includes multiple pore types such as intergranular dissolved pores, intragranular dissolved pores, intercrystalline micropores, and a small amount of primary intergranular pores (Fig. 7o–t). Intergranular pores refer to pores between mineral grains. During diagenetic evolution, primary intergranular pores are formed by mutual support and overlap between brittle grains such as quartz and calcite, and between mineral grains and detritus. SEM showed that intergranular pores in the Fengcheng Formation shale oil reservoirs of the Mahu Sag, Junggar Basin, are mostly of the micrometer scale, ranging from a few micrometers to tens of micrometers. The pores are mainly among quartz, feldspar, and quartz and feldspar particles. The pore morphology is mostly elliptic, triangular or polygon, and elongated or irregular.
Secondary pores refer to the pores formed by the influence of diagenetic epigenesis after deposition. It includes intercrystalline pores, dissolved pores, and a few dissolved caves. Such pores are important storage spaces for Fengcheng reservoirs. Secondary dissolution pores are caused by selective mineral dissolution. The pores are formed by the complete or partial dissolution of various clastic particles and within diagenetic minerals, such as feldspar grains, calcite grains, dolomite grains, and intermediate pores (Fig. 7b–e). Intercrystalline pores in the Fengcheng Formation shale reservoirs are small, typically no more than a few micrometers, and are mostly formed by late diagenetic metasomatism, such as dolomitization and recrystallization. Intercrystalline pores are more common in authigenic minerals, such as the pores formed between crystalline minerals, such as calcite and dolomite (Fig. 7f). Intercrystalline pore distribution is uneven, with numerous but extremely small pore diameters. The pore-throat diameter is typically less than 1 μm, mostly 100–500 nm. They often coexist with fracture zones and contribute to the formation of sweet spots in tight reservoirs.
Discussion
Diagenesis evolution sequence
Based on the reconstruction of burial and thermal history of the Fengcheng Formation in the Mahu Sag and analysis of the diagenetic environment, sequence, system, and stage, the reservoir is currently in the middle of diagenetic-stage B (Fig. 8). The diagenetic evolution sequence of the Fengcheng Formation is established as follows. Eogentic microcrystalline high-magnesium calcite and aragonite precipitation -penecontemporaneous dolomitization–pyritization -calcite cementation and metasomatism -compaction-chlorite precipitation–dissolution–silicification -illite cementation -ankerite cementation–Na–Ca–Mg-type carbonates (shortite, eitelite, and northupite)-alkaline minerals (sodium carbonate, sodium bicarbonate)-reedmergnerite and late fissure. The results showed that the diagenetic of the Fengcheng Formation is diverse and the diagenetic system is relatively complex. Compaction and dissolution; carbonate mineral cementation, such as calcite and ankerite in the middle diagenetic stage; and clay minerals, such as illite/smectite mixed layers, are the principal controlling factors for the reservoir’s densification. Feldspar dissolution and carbonate particle cementation are critical for the diagenetic reformation of a tight reservoir.
The reservoir space combination type of shale oil
The shale oil-charging channel types identified by core observation, fluorescent TS, and FE-SEM include kerogen networks, tectonic fractures, stylolites, and micro–nanoscale pore-throat systems (Fig. 9). The organic kerogen network is a critical channel system for oil and gas charging and migration. If the hydrocarbon generated by the kerogen reaches a specific concentration, it can be migrated along the kerogen vein into the reservoir. The Fengcheng Formation’s source rocks are rich in organic matter. Among them, kerogen types I–III are distributed in the P1F3, and the main types in P1F2 are II and II1, providing a favorable channel network for shale oil (Piane et al. 2018; Yang et al. 2020).
Tectonic fractures of the Permian in the Junggar Basin were mainly formed in the Hercynian and Indosinian tectonic movements. Affected by the heterogeneity of the rock formations, two sets of conjugate shear fractures occur in the NW–SE and NE–SW of the Mahu Sag (Zhang et al. 2019a, b, c). The NE–SW direction fault controls the fracture development. The extensively developed tectonic fractures in the Fengcheng Formation are critical to source-rock hydrocarbon expulsion. The tectonic fractures developed in dolomite or dolomitic mudstone are mostly high angled with a large cutting depth, and the joint surface is mostly filled with calcite or a carbonaceous pitch, appearing in groups with an obvious direction. Unfilled tectonic fractures are effective shale oil reservoir spaces, and shale oil extravasation along these tectonic fractures is significant. In the Fengcheng Formation without fractures, mineral matrix pores (intergranular, intragranular, and intercrystalline) dominate the reservoir space. The oil-bearing grade of such cored intervals is from the oil trace to the oil spot, and the fluorescence is light yellow and yellow. Therefore, the micro–nanoscale pore-throat system is a vital channel type for shale oil charging.
The oil-bearing grade of terrestrial clastic rocks is oil immersion, with the developing micro–nanoscale pore-throat system. The oil-bearing grade of carbonates and pyroclastic rocks is the oil spot, with the developing micro–nanoscale pore-throat system and stylolite structure, and some are of the oil immersion grade. The oil-bearing grade of salt rocks is the oil spot, with the developing secondary dissolution pore in the microscale and intercrystalline pore in the nanoscale, and some are of the oil residue grade. The oil-bearing grade of mixed rocks is oil residues and spots, with the developing micro–nanoscale pore-throat system and stylolite structure.
Shale oil charging is a complex geological process, and charging and micromigration rarely occur along a single channel. There are numerous stylolite structures in the source rocks of the Fengcheng Formation. The reservoir pore types are mainly secondary dissolution and intercrystalline pores, and the fractures are mainly tectonic (logging, core, and micropore-throat scales) and bedding. Channels with diverse types of geneses and scales interconnect to form a complex pore-fracture network system. This study shows that the Fengcheng Formation possesses two types of source-reservoir channel combination models: tectonic fracture-pore systems (tectonic fracture-type reservoirs) and stylolite-matrix pore-tectonic microfracture systems (shale oil reservoirs), forming the shale oil preponderant charging-channel network. Hydrocarbons generated at an early stage were charged into the micro–nanoscale pore-throat system, changing the wettability of rock particles from water wet to oil wet, increasing the free oil content (Fig. 10).
Conclusion
The results showed that the Fengcheng sedimentary period of the Mahu Sag is in the dry and hot continental lacustrine basin, with a saltwater paleoenvironment and anoxic/lean oxygen conditions. The Fengcheng Formation of the Mahu Sag is dominated by dark-colored and fine-grained sedimentary rocks, with various rock types such as terrigenous fan delta clastic, lacustrine fine-grained carbonate, pyroclastic, and salt rocks. A classification and nomenclature scheme of the alkaline lake-type shale reservoir in the Fengcheng Formation has been formed using three lithologic component endmembers, alkaline mineral content, and sedimentary structure. Currently, the Fengcheng reservoirs of the Mahu Sag are in the mesogenetic stage B. It has experienced four diagenesis processes, including compaction and pressure dissolution, cementation filling, multistage dissolution, and metasomatic diagenesis. Fractures and secondary porosities are the principal reservoir space types in the Fengcheng Formation. This study showed that the Fengcheng Formation has two source-reservoir space combination models: tectonic fracture-pore systems (tectonic fracture-type reservoirs) and stylolite-matrix pore-tectonic microfracture systems (shale oil reservoirs), forming the shale oil preponderant charging-channel network. This study provides theoretical support and a scientific basis for the next step of shale oil exploration and deployment and a decision-making analysis in the Junggar Basin.
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We would like to thank Xinjiang Oilfield Branch Company Ltd., PetroChina for the permission to publish this work.
Funding
This research was supported by the National Science and technology project (project number: 2017ZX050001002), the Petro-China Science and technology Project (Project number: 2019E-2602) and the Petro-China Science and technology (Project number: 2021DJ1801).
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Zhifeng, Y., Yong, T., Xuguang, G. et al. Diagenesis and reservoir space types of alkaline lake-type shale in Fengcheng Formation of Mahu Sag, Junggar Basin, China. Arab J Geosci 14, 2356 (2021). https://doi.org/10.1007/s12517-021-08634-7
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DOI: https://doi.org/10.1007/s12517-021-08634-7