Abstract
The Da’anzhai Member limestone in the central Sichuan Basin holds significant importance as a tight oil-producing formation. Despite its crucial role, the intricate patterns of hydrocarbon enrichment and the elusive geological factors dictating high-yield production have impeded tight oil exploration and development in the Sichuan Basin. This study delves into the geological characteristics of tight oil and identifies key factors influencing high-yield production, utilizing comprehensive data derived from cores, thin sections, well logging, seismic studies, and production tests of the Da’anzhai Member in the western Gongshanmiao within the central Sichuan Basin. Our findings reveal that the primary productive strata for tight oil are the Da 1 (1st Submember of the Da’anzhai Member) and Da 3 (3rd Submember of the Da’anzhai Member) Submembers, characterized by high-energy and low-energy shell beach microfacies. The kerogen type is sapropelic, ranging from mature to highly mature, positioning it as a moderately good hydrocarbon source rock. The predominant lithology of the reservoir consists of coquina and argillaceous coquina, with secondary dissolved pores, fractures, and nano-scale micropores serving as the predominant reservoir spaces. The overall lithology represents a dense limestone reservoir of the pore-fracture type, featuring low porosity and permeability. Critical controlling factors for achieving high-yield production of tight oil encompass lithological composition, fracture development, tectonic position, and source-reservoir configuration. Notably, substantial coquina thickness, fracture development, and the strategic relationship between the lower reservoir and upper source rocks contribute significantly to unlocking high tight oil yields. Additionally, thin-layer coquina emerges as a potential area for realizing increased oil and gas production capacity during later stages of development. This comprehensive analysis sheds light on the intricate dynamics governing tight oil production in the Da’anzhai Member, offering valuable insights for advancing exploration and development strategies in the Sichuan Basin.
Article highlights
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The lithological combination, fracture development, tectonic position, and source-reservoir configuration are the major factors controlling the high-yield production of tight oil
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Substantial coquina thickness, fracture development, and the strategic relationship between lower reservoir rocks and upper source rocks contribute significantly to high tight oil yields.
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Thin-layered limestone plays a crucial role in the oil and gas production capacity of the western Gongshanmiao area as a vital replacement and direction.
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1 Introduction
In recent years, breakthroughs have been made in exploring unconventional oil and gas resources such as shale gas, coalbed methane, and tight oil and gas, which have become sought-after fields and targets of global oil and gas exploration (Hooker et al. 2018; Guo et al. 2018; Li et al. 2019a, 2020a, b, c, 2022a; Ma et al. 2020, 2022; Liu et al. 2020a; Radwan 2021; Li 2022a). Tight oil is a new resource driving China's increasing reserves and production. In particular, progress and discoveries have been made in exploring tight oil in the Junggar Basin, Songliao Basin, Ordos Basin, and Sichuan Basin (Liu et al. 2020b; Mahdi et al. 2021; Pang et al. 2022; Tang et al. 2022; Xie et al. 2022). Tight oil refers to oil accumulations sandwiched in or immediately adjacent to dense clastic rock or carbonate rock reservoirs of high-quality oil source formations and has not migrated over long distances on a large scale. The physical property limits of the dense layer are determined as the permeability of less than 1 × 10−3 µm2 under standard atmospheric pressure and the permeability under the subsurface overburden pressure of less than 0.1 × 10−3 µm2 (Guo et al. 2019; Hu et al. 2022a, b; Tian et al. 2022). The shale gas in China's Sichuan Basin has become the world's second-largest shale gas production base after the United States, whereas the progress of tight oil exploration and development has been slow (Nie et al. 2020; Fan et al. 2020a, b; 2022; Li et al. 2022b, 2023a, 2023b). The Da’anzhai Member of the Jurassic Ziliujing Formation is the most important oil source formation in the Sichuan Basin, and many oil reservoirs and oil-bearing structures have been discovered in the central and northern regions of Sichuan. By the end of 2021, 50% of the crude oil had been produced by the Da’anzhai Member of the Ziliujing Formation in the Sichuan Basin, demonstrating the high resource exploration and development potential of the Da’anzhai Member (Jia et al. 2012; Pang et al. 2018; Li et al. 2020a; Luo et al. 2022; Chang and Yin 2022). Exploration and development practices have confirmed that this type of reservoir is ultra-tight and generally has no natural production capacity but can yield industrial production capacity only through artificial fracturing. Lithological combination and characteristics, fault (fracture) development degree, diagenesis, and source-reservoir configuration may be the principal factors affecting tight oil enrichment and high yield. Yu et al. (2018) investigated the diagenetic characteristics of the thick-shelled oyster reef deposits in the Cretaceous Mishrif Formation of the H oilfield in Iraq and their control on reservoirs. Based on changes in relative sea level, lithological evolution of thick-shelled oyster reefs, and sedimentary structural characteristics, a single intact thick-shelled oyster reef was divided into four lithological intervals. The relationships between lithological combinations, diagenetic processes, and hydrocarbon occurrences were analyzed separately. Jiang et al. (2023) classified four types of lithological combinations of shale in the marine-continental transitional facies of the Ordos Basin based on core, outcrop, and logging response characteristics and provided exploration and development suggestions for shale oil in different lithological combinations. Li et al. (2020b, 2021) researched fracture characteristics of carbonate reservoirs in the Jiulongshan structure of the Sichuan Basin using outcrop, core, imaging logging, production testing data, and numerical simulation of paleostructural stress fields. They pointed out that the degree of fracture (fault) development is a key factor affecting the high production of tight carbonate reservoirs. Rock mechanics parameters are the basis for stress field numerical simulation in the study of tight reservoir fractures (Rasouli and Vaseashta 2023; Dalla Chiesa et al. 2022; Shan et al. 2021; Wang and Wang 2021). Based on the study of natural fracture characteristics, Wu et al. (2022a, 2022b) clarified the influence of natural fractures in shale on hydraulic fracturing using numerical simulation methods and then analyzed the relationship between natural fractures and productivity. However, it remains unknown whether these influencing factors control the productivity of the Da’anzhai Member, and the main controlling factors affecting the exploration and development of tight oil reservoirs in the study area of the Da’anzhai Member remain to be investigated.
The Da’anzhai Member primarily comprises shale and limestone, serving as hydrocarbon source rock and reservoir space for tight oil. The lithological combination of substantial limestone thickness and a well-structured source-reservoir arrangement forms the foundation for the accumulation of tight oil. Furthermore, the limestone reservoir exhibits low porosity, permeability, and heterogeneity (Qiao et al. 2016). The fractures within this reservoir are paramount as primary storage spaces and conduits for the migration of tight oil (Afsar et al. 2014). The determination of whether the limestone in the Da’anzhai Member can attain high productivity hinges significantly on this aspect.
This comprehensive study focuses specifically on the western region of Gongshanmiao in the central Sichuan area. By integrating data from various sources such as core samples, thin sections, well logging, seismic studies, and production dynamics, the research delves into the reservoir characteristics, degree of fracture development, and structural conditions of the Da’anzhai Member limestone. The analysis adeptly tackles the challenges posed by the intricate enrichment patterns and robust heterogeneity of tight oil, pinpointing the key factors that exert control over well productivity (Su et al. 2020). Concurrently, it sheds light on the distribution of tight oil in the Sichuan Basin. The findings of this study carry substantial theoretical and practical implications, offering valuable insights for the exploration of tight oil in the study area and analogous regions. Importantly, the research outcomes effectively guide the exploration of tight oil and gas in the designated area and similar geological contexts.
2 Geologic setting
The western Gongshanmiao is located between the Gongshanmiao-Zhongtaishan structure in the mid-slope gentle belt of the palace high in central Sichuan, with the Yingshan structure in the east, the Lianchi and Nanchong structures in the south, and the Bajiaochang structure in the west (Fig. 1a) (Lei et al. 2023; Xiong et al. 2023). The major structure is a gentle slope with a south-to-north inclination. There is a slight anticline in the middle, with an undulating height of less than 50 m; the overall development degree of the fault is low, and only some small-scale and short-extending secondary faults are developed on the slope with a steep stratum attitude (Fig. 1b).
In the late Early Jurassic, the central Sichuan area was principally a set of inland deep-semi-deep lacustrine deposits (Fig. 1a) with a relatively stable tectonic setting total thickness of the Da’anzhai Member is between 68 and 120 m. According to the depositional environment and lithological combination characteristics, the Da’anzhai Member can be divided into Da 1(1st Submember of the Da’anzhai Member), Da 2 (2nd Submember of the Da’anzhai Member), and Da 3 (3rd Submember of the Da’anzhai Member) Submembers from top to bottom (Zhu et al. 2022a, b; Liu et al. 2022; Xiong et al. 2023). The overall thickness of the Da 1 Submember is 18–35 m, and the upper section is composed of thick-layer coquina and argillaceous coquina partially intercalated with a thin layer of black argillutite. The thickness of the Da 2 Submember is mostly 35–45 m, with common thin-layer coquina strips on the top and thick-layer black argillutite in the middle and lower sections, making it the major source bed in the study area. The Da 3 Submember is 5–10 m thick and is principally composed of medium-thick-layer gray-brown couquina and argillaceous coquina (Fig. 1c). Among the Submembers, the Da 1 and Da 3 Submembers are major productive strata of tight oil. A number of oil-bearing structures have been found in central Sichuan, such as the Gongshanmiao, Zhongtaishan, Guihua, Lianchi, and Jinhua structures (Xu et al. 2017; Hu et al. 2019; Dong et al. 2022).
3 Samples and methods
This study examined more than 100 m cores of 8 wells, including Gong 4 (Hereafter G4, similar to other wells), G6, and G7, to describe the lithological and fracture characteristics. Thirty tight oil reservoir samples were drilled from the Da'anzhai Member, and X-ray diffraction (XRD), Cast thin section, scanning electron microscopy (SEM), physical property measurements, and other experimental tests were conducted on the core samples (Table 1). More than ten typical samples with a diameter of 2.5 cm were drilled. The porosity and permeability of the samples were analyzed using a helium porosimeter and a gas permeability meter, respectively. The following experiments were then conducted on the remaining samples.
3.1 X-ray diffraction (XRD) experiment
Selecting previously prepared powdered core samples, the powder is pressed into pellets to maintain uniformity and smoothness during X-ray irradiation. The powdered sample is then placed in the XRD, where X-rays are emitted from the X-ray tube toward the sample, resulting in specific diffraction patterns (Cheng et al. 2022). Information about various minerals in the sample, such as their relative abundance and crystalline structure, can be obtained by measuring the diffraction peaks in the pattern.
3.2 Scanning electron microscope (SEM) experiment
The analysis using SEM with argon ion beam milling incorporates the LEICA EM RES102 argon ion beam milling system coupled with a high-resolution field emission scanning electron microscope (FESEM) from FEI (He et al. 2021). The electron beam acceleration voltage is adjustable from 20 V to 30 kV, while the ion acceleration voltage spans from 500 V to 30 kV. The technique employed is Focused Ion Beam Scanning Electron Microscopy FIB–SEM), where a FESEM is equipped with a gallium ion beam positioned at a 52° angle to the electron beam. The gallium ion beam, perpendicular to the sample surface, is employed for precision cutting, while the electron beam scans at a 38° angle to capture high-resolution images of the sample surface. The examined sample area measures approximately 600 µm × 400 µm, enabling meticulous analysis of shale micropores within the micro–nano range and precise differentiation of nanopores within the 1–2 nm range (Abraham-A et al. 2022; Zhu et al. 2022a, b; Li et al. 2023a).
In addition, the production data of 78 wells (e.g., Shi 3, S5, S6, G4, G9, G11, etc.) in the study area were collected and organized to classify the types of wells (high-yield wells, industrial wells, and low-yield wells) and analyze the factors that contribute to the high yield of tight oil. At the same time, the conventional well logging data of 78 wells and the imaging well logging interpretation data of some wells were collected to carry out well-logging lithology and lithofacies identification. To analyze the seismic response patterns of high-yield oil wells, seismic profiles of more than 10 typical wells were obtained. The above-described data were obtained from PetroChina Southwest Oil and Gas Field Company.
4 Results
4.1 Depositional characteristics
Lake basin deposits dominated the early Jurassic of the Sichuan Basin, and the basin entered the evolution stage of the annular depression foreland basin, forming a pattern of being steep in the north and gentle in the south. The study area is located in the central and northern parts of the lake basin, near the lake basin's center. The depositional environment is predominantly characterized by the shore-shallow lake and semi-deep lake subfacies, with a primary emphasis on the development of shell beach depositional microfacies (Tan et al. 2011; Lai et al. 2015). The Da 2 Submember, as a whole, is situated in a semi-deep lake environment near the sedimentary center of the Da’anzhai Basin, characterized by calm and relatively deep water conditions. Positioned below the storm wave base, the hydraulic conditions are extremely weak, with low energy levels. Consequently, the development of shell beaches in this region is limited, marking the primary deposition period for dark mud shale. Based on parameters such as the Da 1 and Da 3 Submembers' thickness and the shale-to-limestone ratio, the Da’anzhai Member in the study area is stratified into high-energy and low-energy shell beach depositional microfacies.
Based on the examination of core samples, thin sections, and well logging data within the study area, and considering the regional depositional setting, lithological compositions, and distributions, the area is classified into littoral-lacustrine subfacies (including high-energy shell beach and low-energy shell beach microfacies), semi-deep lake subfacies (Table 2) (Xu et al. 2019; Lei et al. 2023). The lithology of the high-energy shell beach primarily comprises thick-bedded, blocky pure shell limestone, characterized by low gamma-ray (GR) values and containing minor interbedded mudstone layers. The low-energy shell beach is typified by thin interbeds of argillaceous shell limestone and mudstone with moderate GR values. The semi-deep lake subfacies are predominantly composed of thick-bedded mud shale (with occasional occurrences of shell limestone), exhibiting high GR values. Utilizing this information and single-well and multi-well sedimentary facies analyses, the sedimentary facies distribution characteristics of the Da’anzhai Member were delineated.
During the deposition period of the Da 3 Submember, the water depth increased, and the water energy intensified as the basin started to develop. Due to the relatively short duration of the Da 3 Submember, the stable and extensive deposition of high-energy shell beach, it occurred predominantly in the uplifted portions of the water with the strongest wave action. This setting facilitated the formation and development of intertidal limestone, primarily depositing thicker and more intact intertidal shells.
As the Da 1 Submember deposition period commenced, a regression occurred, leading to shallower water conditions. With reduced water energy, processes such as transport and sorting weakened. Consequently, the lithology transitioned to muddy, mud-rich intertidal limestone, with a relatively lower mud content compared to high-energy shell beaches and smaller thicknesses.
On a planar scale, the distribution range of high-energy shell beaches during the Da 3 Submember is larger than that during the Da 1 Submember. The Da 3 Submember exhibits a dispersed and patchy distribution in the study area (Fig. 2a), while the Da 1 Submember is predominantly found in the northern and northwestern parts of the study area (Fig. 2b). Low-energy shell beach is less developed during the Da 3 Submember, mainly in the southern part of the study area, where the Da 1 Submember is more extensively developed, albeit on a smaller scale.
4.2 Characteristics of hydrocarbon source rock
The depositional stage of the Da’anzhai Member of the Sichuan Basin during the Jurassic occurred during the lake flooding period, was not affected by foreign matters, and had an under-compensated "hungary" lake basin background (Zhao et al. 2013; Zhang and Tang 2023). In particular, developed during the longest lake flooding period, Da 1 and Da 3 Submembers are a set of shallow lake-semi-deep lacustrine deposits with strong reduction conditions. They are more than 70 m thick in the Yilong-Dazhou area and are major hydrocarbon source rocks of self-generating and self-storage oil and gas reservoirs in central Sichuan. According to the research results of Hou et al., the total organic carbon (TOC) content of dark argillutite in the Da’anzhai Member is 0.54–2.32%, with an average of 1.30%. The oil production potential rate (S1 + S2) is 0.38–13.33 mg/g, with an average of 4.46 mg/g, the hydrocarbon production index (PI) is 0.22–0.51, with an average of 0.32, the hydrogen index (HI) is 49.91–360.34 mg/g, with an average of 201.09 mg/g, the available carbon (PC) is 0.03–0.77%, with an average of 0.37%, and the hydrocarbon index (HCI) is 20.33–214.22 mg/g, with an average of 97.73 mg/g. This shows that the dark argilutite in the Da’anzhai Member has high organic matter content and is a set of medium-good hydrocarbon source rocks. The organic matter's vitrinite reflectance (Ro) is 0.78–1.76%, with an average of 1.16%; the sapropelic type dominated the kerogen (Chen et al. 2005; 2015; Du et al. 2005). Both the burial depth and maturity of organic matter of argillutite increase from south to north in the Da’anzhai Member, and most areas are in the peak period of oil production, with favorable oil production conditions.
4.3 Tight oil reservoir characteristics
4.3.1 Lithological characteristics
The lithology of the Da’anzhai Member in the west of Gongshanmiao is mostly sedimentary rocks mixed with terrigenous clasts and carbonates under the freshwater lake system. According to the cores, thin section observation, well logging curves, and XRD mineral composition analysis, the major lithology is coquina, argillaceous coquina, and mud-bearing coquina, of which the former two are major reservoirs (Moosavi et al. 2022; Chen et al. 2019; Zhang et al. 2020; Liu et al. 2021).
Coquina includes crystalline limestone, sparry coquina, and micrite coquina, mostly grayish brown and thick-layer blocks (Subrahmanyam and Reddy 2008; Lima et al. 2020). As microscopy observations show, the shell is closely directionally aligned and highly fragmented. The coquina mostly comprises biological carbonate rock supported by 30–90% of biological debris. The biodetritus was mostly that of lamellibranchiates, with a small amount from gastropods and ostracods. The shape of the well logging curve is generally flat and exhibits a stable box, and the natural gamma curve presented low values, which are 10–30 API in most cases; the deep and shallow dual-lateral resistivity is high and is greater than several thousand Ω m in most cases. The mineral composition is mostly calcite, accounting for 92%, followed by mud, which has a content of 4.5% (Fig. 3a).
Argillaceous coquina mostly is dark gray-grayish black thin-layer strips and is observed to be directionally aligned and highly fragmented by microscopy; the interstitial matter between the shells is mostly argillaceous, with a content of 25–45%. The biodetritus is dominated by lamellibranchiates, including a small amount of ostracoid biodetritus, and the shell is dominated by aragonite, with a small amount of calcite. The well logging curve is micro-dentate, the natural gamma value is higher overall, generally between 50 and 70 API, and the deep and shallow dual-lateral resistivity is lower overall, with a smaller variation range. The mineral composition is mostly calcite, accounting for 68.3%, and the mud content is higher, reaching 26.9% (Fig. 3b).
Mud-bearing coquina can be subdivided into mud-bearing sparry coquina and mud-bearing micrite coquina. It is mostly gray-dark gray and is found in medium-thin layers, and the shells were observed to be complete but disorderly aligned by microscopy. In addition to calcite, a small amount of argillaceous matter is present between the shells, with a content of approximately 10–25%. The well-logging curves are mostly finger-shaped, the natural gamma value is slightly higher than that of the coquina, and the deep and shallow dual-lateral resistivity is slightly lower than that of the coquina, with an evident tooth shape. The mineral composition is still dominated by calcite, accounting for 79.3%, which is between the coquina and the argillaceous coquina, with a content of 10–25%; the content of argillaceous matter is 18% (Fig. 3c).
4.3.2 Types and characteristics of reservoir spaces
According to the genesis of pore spaces in carbonate reservoirs, they are generally classified into primary pore, secondary pore, and fracture (Zhang et al. 2015; Zhao et al. 2013). According to the observation of casting thin sections and scanning electron microscopy, the primary pore is relatively limited in the study area, while nano-scale micropores are highly developed. Therefore, the reservoir space of the tight oil reservoir in the Da’anzhai Member mainly included secondary dissolved pores (holes), fractures, and nano-sized micropores. The secondary dissolved pores (holes) can be divided into intergranular (intragranular) dissolved pores and intergranular (intragranular) dissolved pores; the fractures were mostly macroscopic structural fractures and microfractures.
4.3.2.1 Secondary dissolved pores (holes)
Intergranular (intragranular) dissolved pores: the dissolved pores in the study area are nearly round and irregular and are mostly distributed along sutures and microfractures in the shape of a string of beads or are directly dissolved by the shell fragments (Xu et al. 2021; Ahmad et al. 2021; Marghani et al. 2022). Due to dissolution, the pore morphology is irregular, and the pore size generally ranges from a few microns to several hundred microns, mostly showing independent pores (Fig. 4a). In addition, there is also a small amount of intergranular pores and intergranular solution pores between the fractures or the sparry calcite filling of solutional caves (Fig. 4b) (He et al. 2021). Solutional caves are mostly formed by further erosion and expansion of the pores formed in the early stages (Hu et al. 2022a, b). Although the number of secondary dissolved holes is small, they are well-connected with the fractures, effectively improving the reservoir permeability and making the secondary dissolved hole an important oil and gas reservoir space.
Intergranular (intragranular) dissolved pores: calcite in coquina often recrystallizes into polygons, forming intergranular gaps between calcite crystals, and these pores are mostly developed in crystallized mesoscopic grains with oil traces or asphalt filling in the gaps in most cases.
4.3.2.2 Fractures
Tectonic fracture is formed by rock cracking under the action of structure (Fan et al. 2020a, b; He et al. 2022a; Li et al. 2022a, b, c, d). Most of the fractures are narrow and small low-sloped ones in the horizontal direction, and few are high-angle fractures and large fractures extending in a particular direction (Fig. 4c) (Gao 2019; Hou et al. 2020; Wang et al. 2022). The fracture wall is often corroded, and the calcite in the fractures is semi-fully filled with oil immersion and oil traces (Fig. 4d). Such fractures have a reservoir capacity and can connect many holes or matrix pores, increasing the connectivity between pores (Yang et al. 2022; Li 2021).
Dissolution fracture: new fracture branches or independent fracture systems formed by the dissolution and transformation of early fractures under fluid action (Tan et al. 2022; Li 2022b; Li et al. 2019b). For example, the small holes formed along the dissolution of early fractures seen in the core are distributed in the shape of a string of beads, not only developed in the coquina but also observed in the argillutite, and distributed in a serpentine or dendritic shape (Fig. 4e). Dissolution fractures make the fractures more interactive to a certain extent, making the connection between various types of fractures closer and more frequent.
Micro-fracture: micro-scale fractures principally include tectonic micro-fractures, diagenetic micro-fractures, and calcite cleavage fractures. The width of the fractures is mostly less than 0.02 mm (Fig. 4f). Compared with macro-tectonic and non-tectonic fractures, although the monomer scale of the micro-fracture is much smaller, it far outnumbers the former two types, has reservoir capacity, and plays a major role in permeability, connecting a large number of other finer pore and fracture spaces.
Non-tectonic fracture: including bedding fractures and diagenetic fractures (Fan et al. 2024; Dong et al. 2020). Bedding fractures are less developed in the layered mud-bearing and argillaceous coquina and are mostly developed at the layer where the mesoclastic layer meets the mudstone. The parallel bedding is generally narrow, and small dissolution holes can sometimes be observed along the fractures (Fig. 4g). Diagenetic fracture mainly refers to that formed under the action of diagenetic compaction. The non-tectonic fracture has a short extension distance without a clear extension direction.
4.3.2.3 Nano-scale pores
The nano-scale pores in the coquina are also relatively developed and are characterized by an irregular shape, isolated distribution, and small pore size (Sun et al. 2022; Guo et al. 2022). The pore size of nano-scale pores is mostly 60–4000 nm and, in most cases, is less than 250 nm (Fig. 4h, i). In the case of the overall tight reservoir, many of these nano-scale pores interact with each other, improving the reservior property of the tight oil reservoir.
4.3.3 Reservior property
Examination of the results of the porosity and permeability analysis of different lithology samples from 7 wells in the study area shows that the overall physical properties of the reservoir in the Da’anzhai Member are poor, and overall, the reservoir is characterized by low porosity and low permeability. The porosity is 0.3–2.5%, with an average value of 0.90%, and is in the 0.5–1.5% range for 80% of the reservoir. The permeability is between 0.001 and 1.0 mD, and the permeability of most samples is less than 0.1 mD. The physical properties of different lithologies show no noticeable differences. Specifically, when the porosity of the coquina is low, the permeability is still high, indicating that fractures are developed in the lithology in most cases. The mud-bearing and argillaceous coquina show no evident linear porosity–permeability relationship. The porosity and permeability of mud-bearing and argillaceous coquina show a positive correlation. The positive correlation is more obvious when the porosity is less than 1.5% (Fig. 5). In fact, this is related to the samples we used for the physical property experiments. In these lithological samples, fractures are almost undeveloped and micro- to nano-scale pores dominate. When the porosity is relatively low (1.5%), there is a synergistic increase in porosity and permeability. However, as the porosity continues to increase, due to the lack of micro-fractures connecting isolated pores, porosity, and permeability do not increase simultaneously (Yokoyama and Takeuchi 2009; Hossain and Zhou 2015). On the other hand, it also indicates that the degree of fracture development in Coquina should be greater than in the other two lithologies.
5 Discussion
5.1 Determination of the standard for the high yield of tight oil
Jurassic tight oil reservoirs in the Sichuan Basin are highly densified, have a small thickness, change rapidly in the longitudinal and transverse directions, and are highly non-homogeneous. In the development process, there are large differences in single-well productivity, cross-distribution of high-yield, low-yield, and dry wells, and complex geological factors controlling the high yield.
According to industry standards in the petroleum (Ministry of Land and Resources of the People’s Republic of China. Oil and gas reserves calculation specifications: DZ/T 0217-2005 2005), wells within the Da’anzhai Member generally have a depth of less than 2500 m. Consequently, the lower limit for well production in industrial oil flow is 1 ton per day (t/d). When test production exceeds 5 t/d, cumulative production often surpasses 5000 t (Yang et al. 2017). Based on the practical production experience with Jurassic tight oil in the central Sichuan region, and considering the current exploration and development status in the western Gongshanmiao, under similar production systems and geological conditions, wells with test production exceeding 5 t/d and cumulative production exceeding 5000 t are defined as high-productivity wells. Wells with test production below 1 t/d are classified as low-productivity wells, while the remaining fall into the category of industrial wells. There are 46 production wells in the Da’anzhai Member of the area, including 26 high-yield wells (15 wells with a production of 10,000 t) and 9 low-yield wells. Among these, drilled wells with a cumulative output greater than 10,000 t account for 34.7% of the total number of wells, but their cumulative output accounts for 85.0%. A few high-yield wells contribute most of the output and create significant economic effects.
5.2 Main controlling factors of high yield of tight oil
5.2.1 Characteristics of lithological combination
The favorable depositional facies zones of the reservoir in the Da’anzhai Member in central Sichuan are high-energy and low-energy shell beaches (Tian et al. 2017; Xu et al. 2020). High-energy shell beaches in the Da’anzhai Member of the area are mostly developed in the Da 1 Submember and are locally developed in the Da 1 Submember. High-energy shell beaches are a product of the high-energy environment in shallow lakes. The shells are broken by wave elutriation, forming thick pure coquina with a very thin layer of mudstone (shale), which is a favorable facies belt for the development of fractures and holes in later stages; low-energy shell beaches are mostly developed in the bottom section of the Da 1 and Da 3 Submembers; they form a medium-thin layer of mub-bearing and argillaceous coquina due to the relatively weak hydrodynamic conditions, are often interbedded with thin layers of mudstone (shale), and are the main locations for the formation of micron-scale and nano-scale pores (Fig. 6).
Based on the results of thin section identification, well logging interpretation, and dynamic production comparison, for the thick-layer massive coquina developed in the high-energy shell beach environment, the proportion of high-yield wells is the largest in the case of the single-layer thickness of 4–6 m and for thin layers of mudstone (shale) located between the coquina layers. Overall, with the increase in total limestone thickness, there is a certain degree of increase in single-well daily production rate. However, there are still many instances where the total limestone thickness is less than 5 m, yet the daily production rate remains high. Total limestone thickness is just one factor influencing production rate, and its correlation with production rate is not strong (Fig. 7a). Among the 23 high-yield wells in the area, there are 12 wells with 10,000 t of output produced by the layered-massive coquina. For argillaceous coquina in a low-energy shell beach environment, the limestone with a thickness of 1–2 m and thin-layer mudstone (shale) have no equal thickness and are not interbedded is also the most favorable lithological combination for high-yield oil wells. Of the 23 high-yield oil wells in the area, 5 wells (The red data points in Fig. 7b) with 10,000 t of output were produced by the interbed between argillaceous coquina and thin mudstone (shale). Apart from these few wells, there is a general exponential relationship between the thickness of a single limestone layer and the cumulative production capacity (Fig. 7b). Clearly, neither the total limestone thickness nor the thickness of single layers exhibits a strong correlation with production capacity. This further confirms that there are many controlling factors for high oil and gas production in the study area.
The oil source formations of high-yield wells are mostly distributed in the lithological combination belt with thick-layer-massive limestone, a very thin layer of mudstone (shale) and interbedded argillaceous coquina, and a thin layer of mudstone (shale). The oil source formations are well-matched with the high-energy and low-energy shell beaches in the Da 1 and Da 3 Submembers. It can be seen that the lithological combination under the control of the microfacies of the dominant shell beach plays an important role in the enrichment and control of the tight oil reservoir.
5.2.2 Characteristics of fracture development
The tight oil reservoir's matrix pore permeability is poor and insufficient to form an effective reservoir. The superposition of different types of fractures of different origins effectively promotes the development of dissolved pores, holes, and fractures, effectively improves the storage and infiltration capacity of the reservoir, and directly controls the development of tight oil reservoirs and well oil production.
The drilling and logging data of 20 high-yield wells in the study area show that more than 90% of the 10,000 t high-yield wells are developed in the productive stratum, with clear acceleration at the time of drilling, drilling tool emptying, well leakage, and blowout and other oil and gas phenomena; secondary minerals such as natural fractures and calcite crystals are found in the cores or cuttings of the corresponding stratum (Table 3). Moreover, according to the fracture development index forecast by geophysics and the high-yield well overlay planar graph, more than 80% of the high-yield wells are located in the fracture development area with a fracture development index greater than 0.3 (Fig. 8). It is shown that the fracture is an important factor for the enrichment of tight oil in the Da’anzhai Member, and it is also a necessary condition for the oil wells in the study area to achieve high yields.
5.2.3 Tectonic position
The tectonic trace of the whole central Sichuan region is relatively simple, and the tectonic amplitude is relatively flat. The Da’anzhai Member of the study area is characterized by a sloping pattern of being low in the north and high in the south and having a local uplift overall. The stratum is relatively continuous overall. Only small faults are developed in areas under a strong force, such as the local uplift and steep slope in the east. The small faults are mostly found in the northeast and northwest directions. Generally, the local tectonic structure difference will affect tight oil and gas enrichment and high yield. For example, the G65 and G003-1 wells located in the same fault zone that are relatively close to each other vary greatly in production. The two wells’ limestone thickness, porosity, fracture development, and other conditions are similar. Considering that these wells are located in the same fault zone, the fault provides conditions for the migration of oil and gas to the higher position so that the G003-1 well in the higher position has a high yield (Fig. 9); this effect is also observed for the G11 and G003-X14 wells. The area where micro-faults develop is more likely to derive micro-fractures under the tectonic action, improving the oil and gas enrichment ability.
5.2.4 Source-reservoir configuration characteristics
The most important feature of tight oil is the source-reservoir coexistence or the proximity of source and reservoir, and the spatial source-reservoir configuration is the key to controlling the enrichment degree of tight oil (Liu et al. 2017; Shi et al. 2023). Due to the strong heterogeneity of tight oil reservoirs, oil and gas can only undergo short-distance migration and are enriched in hydrocarbon source rocks or adjacent reservoirs. Therefore, near-source accumulation is vital for the enrichment and high yield and is longitudinally manifested as the hydrocarbon source interbedded with the reservoir, hydrocarbon source rocks under reservoirs, and hydrocarbon source rocks overlying reservoirs, corresponding to the three source-reservoir configuration relationships (Fig. 10): source-reservoir interbedding, the combination of lower reservoir rocks with upper source rocks, and the combination of upper reservoir rocks with lower source rocks (Yang et al. 2017).
The tight oil reservoir of the Da 1, Da 2, and Da 3 Submembers of the Da’anzhai Member in western Gongshanmiao shows evident source-reservoir configuration zoning. The combination of lower reservoir rocks with upper source rocks is distributed in the east and north, and the bottom is longitudinally located in the upper part of the Da 1 Submember. The lithological combination of the reservoir is dominated by thick-layer-massive coquina; the thickness of the coquina in the east near Gongshanmiao Oilfield is 4–6 m, and the thickness of the single-layer coquina in the north near Zhongtaishan can reach 10 m. The stably developed dark organic matter-rich mudstone (shale) lies beneath the coquina, micro-faults and fractures develop in the area, and the oil and gas near-source migration efficiency is high, forming the most favorable source-reservoir combination. The existing high-yield wells with more than 20,000 tons of output are located in this area. The combination of upper reservoir rocks with lower source rocks is distributed in the east, and the hydrocarbon source rock in the Da 2 Submember overlays the reservoir rock in the Da 3 Submember. The reservoir lithological combination is dominated by thick-layer coquina with a thickness of 4–6 m, the microfractures are relatively developed, and the dark argillute in the Da 2 Submember is more than 20 m thick. This forms a relatively favorable source-reservoir combination. The existing high-yield wells with an output of 10,000–20,000 t or higher are located in this area. The source-reservoir interbedding type is widely distributed in the study area. It is commonly found at the top or middle and upper part of the Da 2 Submember and the bottom of the Da 1 Submember. The hydrocarbon source rock and the reservoir are interbedded with unequal thicknesses. The lithological combination is mostly argillaceous coquina with a thin layer of mudstone or thin interbeding and is 0.5–3 m thick. This forms a sub-favorable source-reservoir combination. The existing high-yield wells with more than 5000–10,000 t output are mostly distributed in this area.
5.3 High- yield well patterns in tight oil reservoirs
5.3.1 Geophysical response characteristics of high-yield tight oil wells
According to the statistics for the perforated interval of the well under test, the major oil source formations of the high-yield wells are located in the development section of thick-layer (≥ 3 m) limestone, but some high-yield wells are still present in the thin-layer (< 3 m) limestone. Therefore, the geophysical response characteristics of high-yield wells were analyzed based on thickness.
By collecting statistics regarding the logging values of thick-layer limestone oil source formations of 16 typical high-yield wells in the Da’anzhai Member and its surrounding areas, natural Gamma, acoustic time difference, and resistivity were selected for intersection analysis. There was no evident difference in the distribution of the logging data between the high-yield wells in the Gongshanmiao and Wannanchang areas. The natural Gamma (Fig. 11a), acoustic time difference (Fig. 11b), and resistivity values were 14–32 API, 48–56 us/ft, and 300–5000 Ω m, respectively.
Based on the collected statistics of the response characteristics of various types of drilled wells for conventional seismic profiles, they can be roughly divided into three seismic response characteristics: encountering large faults while drilling or close to large faults, encountering small faults or distortions while drilling, and other forms without evident distortion and variation. For example, the coquina of the G17 well in the Da 3 Submember is 6–7 m thick, with oil saturation of approximately 85–90%, limestone porosity of 2.8–3.2%, and favorable petroliferous and physical properties (Fig. 12a). Moreover, the Da 3 Submember is located at the micro-amplitude structure's turning end, developing small twists and turns. At the same time, it is close to the fault in the northeast direction and develops micro-fractures (Fig. 12b, c). The test output of the well was 6.15 t/d, and the cumulative output by the end of 2020 was 25,481.07 t.
Similarly, the acoustic time difference and resistivity values of high-yield wells in the study area, such as J34, J38, and J15, were selected for the intersection. Excluding the data and abnormal data of the increased time difference of sound waves caused by fractures, the characteristics of the thin interbed that may achieve high yield were obtained: when the sound waves were 52–82 us/ft, the resistivity was 20–600 Ω m; more than 70% of the data are distributed in this range. The statistics of the geological, logging, and seismic characteristics of limestone in the thin-layer section of the high-yield wells in the study area show that the thin-layer sections of the high-yield wells, including G11, G003-1, G47, G111, S3, S11, and N5, contributed little to the output.
5.3.2 Comprehensive patterns of high- yield well
The above analysis shows that the characteristics of lithological combination, fracture development degree, tectonic position, and source-reservoir configuration jointly affected the high yield of tight oil wells (Li et al. 2022c; He et al. 2022b). High-yield wells have clear logging and seismic response characteristics compared to low-yield wells. Combined with lithological combination, fracture development, and analysis of reservoir conditions in the study area, the major characteristics of high-yield wells were summarized (Table 4). In thick-layer limestone, high-yield wells generally had the following characteristics: the thickness of the pure limestone section is approximately 4–6 m (up to 9–13 m in the Wannianchang area); there are fracture responses on the logging curves, seismic prediction or logging; the oil saturation (> 80%) and limestone porosity (2.0–3.5%) are high; the natural Gamma is between 14 and 32 API; the acoustic compensation wave is between 48 and 56 us/ft; resistivity is between 300 and 5000 Ω m; located at the position with a high fracture density (> 0.3), less strongly related to the tectonic position. The seismic test data show that the high-yield wells are located in the favorable area where the reservoir overlaps with fractures. Thin-layer limestone may contribute to high-yield wells to a certain extent and can be used to tap the production potential and improve recovery.
6 Conclusions
Tight oil is a significant unconventional hydrocarbon resource in the Sichuan Basin, following shale gas's extensive exploration and development. The tight limestone reservoir in the western Gongshanmiao serves as a typical representative. However, there is considerable variation in well productivity in this area, and the controlling factors for the high-yield accumulation of oil and gas remain unclear. This lack of clarity poses challenges for the large-scale commercial development of tight oil. This paper begins by examining geological characteristics and analyzes the primary controlling factors for the high-yield accumulation of tight oil, ultimately establishing a model for high-yield wells in tight oil reservoirs. The key conclusions drawn from this study include:
-
(1)
A typical low-porosity and low-permeability limestone reservoir characterizes the Da'anzhai Member in the western Gongshanmiao area of Central Sichuan. High-energy and low-energy shell beaches dominate sedimentary microfacies. The reservoir exhibits diverse storage space types and a complex structure, representing a typical pore-fracture reservoir. Fractures enhance the reservoir porosity and connect pores within intricate structures, leading to an exponential increase in permeability.
-
(2)
Fracture development is the key factor for high and stable yield. The wells with well-developed fractures generally yield high production from the reservoir. Tectonic positions and fractures control oil and gas enrichment by affecting the degree of development of micro-fractures. Combining upper reservoir rocks with lower source rocks is the most favorable source-reservoir configuration combination; the oil and gas produced by the dark mudstone in the Da 2 Submember migrate upward to the Da 1 Submember.
-
(3)
The characteristics of lithological combination, fracture development degree, tectonic position, and source-reservoir configuration are controlling factors for the high yield of tight oil. A single layer of shell limestone with a thickness of 4–6 m represents the most favorable lithological combination. Fracture development is a key factor for achieving high production in oil wells. Structural locations and faults control the enrichment of oil and gas by influencing the degree of development of micro-fractures. By controlling the degree of tight oil enrichment, the' down-generation, up-storage' configuration is the most favorable source-reservoir combination.
Availability of data and materials
The data are available from the corresponding author upon reasonable request.
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Funding
This study was financially supported by the Open Funds of National Key Laboratory of Oil and Gas Reservoir Geology and Exploitation (Southwest Petroleum University) (No. PLN2023-31), the Joint Fund for Innovation and Development of Chongqing Natural Science Foundation (No. 2023NSCQ-LZX0184), the National Natural Science Foundation of China (No. U20A20266), and the Key R and D Project of the Deyang Science and Technology Plan (No. 2022SZ049).
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CF: Writing—review and editing, writing—original draft, data curation; SN: Writing—original draft, formal analysis. HL: Writing—review and editing, writing—original draft, data curation, validation. QP, XS, SQ, MZ, and ZY contributed to formal analysis, validation, and reviewing.
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Fan, C., Nie, S., Li, H. et al. Geological characteristics and major factors controlling the high yield of tight oil in the Da’anzhai member of the western Gongshanmiao in the central Sichuan basin, China. Geomech. Geophys. Geo-energ. Geo-resour. 10, 67 (2024). https://doi.org/10.1007/s40948-024-00783-9
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DOI: https://doi.org/10.1007/s40948-024-00783-9