- 1State Key Laboratory of Petroleum Resources and Prospecting, China University of Petroleum, Beijing, China
- 2School of Earth Sciences, China University of Petroleum, Beijing, China
- 3National Joint Engineering Research Center for Shale Gas Exploration and Development, (Chongqing Institute of Geology & Mineral Resources), Chongqing, China
- 4Key Laboratory of Shale Gas Exploration, Ministry of Natural Resources (Chongqing Institute of Geology & Mineral Resources), Chongqing, China
- 5School of Earth Sciences and Engineering, Xi’an Shiyou University, Xi’an, China
- 6Xinjiang Oilfield Company, PetroChina, Fukang, China
Chemical composition of sediments is often used to evaluate paleoclimate condition, provenance, tectonic setting, depositional condition, and paleoproductivity. However, the validity of these proxies has long been questioned. The comprehensive use of organic and inorganic multi-indicators in combination when interpreting issues related to terrestrial shales should be advocated. The paleodepositional environment, origin of organic matter (OM) and factor controlling OM accumulation in the Early Jurassic Badaowan (J1b) and Sangonghe (J1s) as well as Middle Jurassic Xishanyao (J2x) lacustrine shales in the East Fukang Sag are reassessed by using organic geochemical characteristics of the OM. Some previous knowledge is updated, and some knowledge is further supported by more evidence. The typical clay-rich shale developed under a lacustrine sedimental environment, and the thermal maturity of these organic-rich shales has entered the oil window and formed economic hydrocarbon potential for the tight-oil and shale-oil reservoirs. The paleoclimate conditions of the study area were warm and humid from the Early to Middle Jurassic periods but were colder and drier after the Middle Jurassic period. The salinity of the water column ranged from freshwater to brackish conditions. The J2x Formation was deposited under oxic conditions, while J1b and J1s formations developed under suboxic and reducing environmental conditions. The J2x Formation OM mainly derived from higher plants was deposited in a terrestrial environment,while the OM of J1b and J1s formations was a mixed OM derived from higher plants and bacteria with little algae deposited under bay/estuary environments alternated with terrestrial environments. It is effective to reflect the paleoclimate by element index and judge the salinity by the updated element thresholds, but it is not effective to evaluate the paleoredox conditions by common elemental ratios and to evaluate the paleoproductivity by Ba in the study area.
1 Introduction
Chemical composition of sediments, i.e., elements including major, trace and rare earth elements, are often used to evaluate paleoclimate conditions, provenances, tectonic settings, depositional conditions (i.e., redox and salinity conditions), and paleoproductivities (e.g., McLennan, 1993; Tribovillard et al., 2006; Zhang et al., 2013; Schoepfer et al., 2015; Shen et al., 2015; Arsairai et al., 2016; Liu et al., 2020; Qiao et al., 2022a and b; Wu et al., 2022a). However, the validity of these proxies has long been questioned. First, some elements are not affected by a single factor and are used to interpret different issues by different scholars, which cannot guarantee a single variable and results in conclusions lacking a single constraint. For example, Cu was used to interpret paleoproductivity, salinity, paleoclimate conditions and hydrothermal activity (Choi and Hariya 1992; Tribovillard et al., 2006; Wu et al., 2022a). Second, the Earth’s material composition is not uniform, thereby must result in a wide variation in chemical compositions of different weathering provenance, so the chemical composition of weathering provenance must associate with that of the sediment, but it was always ignored. Third, many elements are enriched in sediments via not only abiotic but also biotic processes (Algeo and Maynard, 2004; Tribovillard et al., 2006; Chen et al., 2015a). Considering the above reasons, the information conveyed by the chemical composition of sediments is multiple and complex, especially for the terrestrial lake basins where the ecosystems are relatively fragile. Therefore, it is not sufficient to evaluate the above issues directly through inorganic elements without considering organic matter (OM) itself. Moreover, based on the organic and inorganic indicators, the interpretation of sedimentary environment conditions was often inconsistent. This complexity, as well as uncertainty, is largely rooted in the fact that the chemical composition of sediments is largely determined by a wide variety of factors including the initial weathering provenance composition, transport distance, as well as the processes of weathering, erosion, deposition, and burial diagenesis (Johnsson, 1993). All the time, some scholars tried to improve the reliability of these indicators via kinds of methods (Wei and Algeo, 2020; Cao et al., 2021), for instance, the proposal of the enrichment factor (EF) (Algeo and Maynard, 2004; Tribovillard et al., 2012). However, this cannot solve the above problems once and for all. Algeo and Liu (2020) as well as Algeo and Li (2020) argued that some common parameters, e.g., V/(V+Ni), V/Cr, and Ni/Co, are not valid based on thresholds proposed by Jones and Manning (1994) and advocated for the discontinuation of these indicators. Since sedimentary environments and OM enrichment mechanisms act directly on and are reflected in OM, the joint use of organic and inorganic indicators when interpreting issues related to terrestrial shales should be advocated.
The Fukang Sag is one of the most important sags in the Junggar Basin. It developed three sets of lacustrine shales during the Jurassic period, i.e., the Early Jurassic Badaowan (J1b) and Sangonghe (J1s) formations as well as the Middle Jurassic Xishanyao (J2x) Formation. These shales are low-mature and mature with significant hydrocarbon generation potential at present (cf. Qiao et al., 2020). Qiao et al. (2020) interpreted the paleoclimate condition, depositional environment condition, palaeoproductivity and OM accumulation mechanism based on major and trace elements. However, these evaluations lack more direct and valid evidence derived from organic geochemistry. This paper focuses on the OM in these Jurassic lacustrine shales in the East Fukang Sag. Paleodepositional environments, origins of OM and factors controlling OM accumulation are reassessed by evaluating the geochemical characteristics of these OM and more effective indicators. Some previous knowledge is updated, and some knowledge is further supported by more evidence.
2 Geological setting
The Junggar Basin, which is a typical Upper Palaeozoic, Mesozoic, and Cenozoic superimposed basin, covers an exploration area of around 130,000 km2 in NW China (Chen and Shi, 2003; Cheng et al., 2022; Figure 1A). The basement is combined by the Precambrian crystalline and part of the Hercynian folded basement. The tectonic evolution can be divided into four stages which are a marine and residual marine foreland basin during the Late Carboniferous-Early Permian period, a continental foreland basin during the Middle-Late Permian period, an intracontinental oscillatory depression basin during the Mesozoic period, and a regeneration foreland basin during the Cenozoic period (Cao et al., 2005; Chen et al., 2015b). These tectonic evolutions were controlled by multiphase tectonic cycles including the Hercynian, Indosinian, Yanshanian and Himalayan orogenic events (Wan et al., 2015).
FIGURE 1. (A) The location of the Junggar Basin at present in China, (B) its structure outline map (the area of lake in J1 is after Bian et al. (2010) and in J1s is after Zhu et al. (2017)) and (C) the study area.
The Fukang Sag is the largest hydrocarbon-generating sag in the basin, which is surrounded by the Beisantai High and Shazhang Fault-fold Belt to the east, the Huomatu Anticlinal Belt and Fukang Fault Zone to the south, the Monan High to the west, and the Baijiahai High and Mosuowan High to the north at present (Figure 1B). The sag is located in the central depression belt of the basin presently (Figure 1B) and is characterized by a NE-SW-trending monocline (Cao et al., 2017a; and b; Figure 1C) with a dip angle of <3° under the effects of the rapid initial uplift during the Early Jurassic and slow uplift during the Middle Jurassic on the southern margin of the basin, respectively. The stratigraphic successions in the Fukang Sag cover from the Carboniferous to the Quaternary deposits with the largest thickness of roughly 10 km, in which the Carboniferous, Permian, Triassic, and Jurassic successions developed organic-rich shales (Chen et al., 2003a; 2003b). The Jurassic strata can be subdivided into five units including the J1b, J1s, J2x, Toutungou (J2t), and Qigu (J3q) formations based on stratigraphic contact, lithological association and sedimentary cycle. The investigated area developed a shallow intracontinental lacustrine setting with depositional faces of lacustrine, deltaic, fluvial, and alluvial fan under a low-amplitude oscillating tectonic setting during the Early to early Middle Jurassic period (the J1b, J1s, and J2x formations) (e.g., Cao et al., 2017b). The lithology of the J1b, J1s and J2x formations is mainly composed of coal seam, organic-rich shale, siltstone, conglomerate, and sandstone (Figure 2). Then, the scale of the lacustrine area shrank rapidly because of the Early Yanshanian orogeny (Cao et al., 2017b) during the late Middle-Late Jurassic periods. These periods developed three depositional faces including shallow lacustrine, fluvial, and deltaic facies characterized by the successions with lithology dominated by organic-rich shales, siltstone, and sandstone (the J2t and J3q formations). Most of the faults are NE-trending and E-W-trending normal faults, which are confined to the Jurassic strata (Cao et al., 2017a). The fault throws are generally ranging from tens to hundreds of meters and the strike length is <2 km.
FIGURE 2. The stratigraphic column, distributions in porosity, oil saturation, TOC content, and Rock-Eval data, as well as compositions of extractable organic matter of the EF 2 well for the Jurassic organic-rich shale in the East Fukang Sag, Junggar Basin, China TOC and Rock-Eval data after Qiao et al. (2020).
3 Sampling and analytical methods
3.1 Samples and data
The studied samples came from the same wells discussed in Qiao et al. (2020). 80 samples were used to perform hydrocarbon extraction and fractionation as well as quantification of each compound and gas chromatography-mass spectrometry (GC-MS) analysis. 37 saturated hydrocarbon fractions were used to perform gas chromatography-flame ionization detector (GC-FID), and stable carbon isotope composition (δ13C) for all fractions was performed in 25 samples. Moreover, clay minerals compositions from 232 samples as well as porosity and oil saturation data from 83 samples that came from EF 2 well were provided by the Xinjiang Oil Field.
3.2 Hydrocarbon extraction and fractionation
Before the test, all analyzed samples were pulverized with a size of <80 mesh to obtain extractable OM (EOM) (i.e., saturated hydrocarbons, aromatic hydrocarbons and resins) by using a Soxhlet extractor system (SEM) with a solvent of dichloromethane (DCM). After the extraction, the addition of activated copper powder and anhydrous sodium sulfate, in turn, to the EOM achieved the removal of water and elemental sulfur, respectively.
The solvents were evaporated to near dryness at below 40°C and then removed into triangular bottles. Adding n-hexane with constant shaking, then performing ultrasonic dissolution. The asphaltene was entirely precipitated after a static settlement for more than 12 h. Then the material was removed to a short-necked funnel stuffed with skimmed cotton and washed with n-hexane until the filtrate was colorless to obtain the EOM which was distilled to 2–3 mL. The asphaltene remained in the short-necked funnel, cotton and triangular bottle was dissolved and washed with DCM until the filtrate was colorless. The EOM composition was eluted with n-pentane for aliphatic hydrocarbon compounds, a mixture solvent of n-pentane and DCM (2:3; V:V) for aromatic hydrocarbon compounds, and methanol for resin compounds, in turn, by using a silica gel (activation in an electric drying oven at 200°C for at least 4 h)-Al2O3 (activation in an electric drying oven at 400°C–450°C for at least 4 h) chromatography. The separated saturated and aromatic hydrocarbon components were volatilized to dry at the condition of <40°C, and the resin and asphaltene components were volatilized to dry at the condition of <60°C.
After the solvent in remnants was evaporated to dryness, the weight difference between the two weighing intervals of 30 min of <0.3 mg can be regarded as constant weight.
3.3 Analyses of molecular geochemistry and carbon isotopes
n-alkanes and isoprenoids in the saturated hydrocarbons were analyzed by GC-FID, while terpanes (m/z = 191; Figures 3A,C) and steranes (m/z = 217; Figures 3B,D) in saturated hydrocarbons, as well as aromatic hydrocarbons including methylphenanthrenes (MPs, m/z = 194; Figure 3E), trimethylphenanthrenes (TMPs, m/z = 220; Figure 3F), chrysene (m/z = 228; Figure 3G), and triaromatic steroid (TMPs, m/z = 231; Figure 3H), were performed by GC-MS.
FIGURE 3. Saturated hydrocarbon characteristics for extracts of organic-rich shale came from (A,C) EF 7 well (3,688 m; J2x) and (B,D) EF 3 well (3,758.7m; J1s), and (E, F, G and H) aromatic hydrocarbon characteristics from EF 3 well shale (3,758.5 m; J1s) for the Jurassic organic-rich shale in the East Fukang Sag, Junggar Basin, China.
The instrument of GC-FID was Shimadzu GC-2010 (Japan) equipped with HP-5MS chromatographic column (30 m × 0.25 mm × 0.25 µm). The carrier gas was 99.999% helium at a velocity of 1.0 mL/min. The inlet temperature was 300°C and the split ratio was 50:1. During the analysis, the initial temperature of the GC oven was 100°C for 1 min, then programmed to raise to 300°C at 4°C/min and hold for 25 min. The temperature of the FID was 300°C with hydrogen of 40 mL/min and air of 400 mL/min.
The instrument of GC-MS was Agilent 7890GC/5977MS (America) equipped with HP-5MS chromatographic column (the stationary phase consists of 95% poly (methylsilicone) and 5% poly (phenylmethylsilicone); 30 m × 0.25 mm × 0.25 µm). The carrier gas was 99.999% helium at a velocity of 1.0 mL/min. During the analysis, the initial temperature of the GC oven was 100°C for 1 min, then programmed to raise to 300°C at 4°C/min and hold for 20 min. The MS was performed in electron ionization (EI+) mode with an ion source temperature of 230°C and ionization energy of 70 eV.
The relative abundance of each compound was calculated from the peak area, and the identification of compounds was based on their relative retention time compared with literature data (e.g., Wu et al., 2022b; Zheng et al., 2022).
The measurement of δ13Corg was performed using a gas isotope ratio mass spectrometer (Finnigan MAT-252) equipped with a 30 m Porapak Q chromatographic column with 20 μm film thickness. The carrier gas was 99.999% helium at a velocity of 1.2 mL/min. During the analysis, the initial temperature was 40°C for 1 min, then programmed to raise to 160°C at 15°C/min. The δ13Corg value was calculated by comparing it to the intentional PDB (Pee Dee Belemnite) standard, and the analytical error was ±0.1‰.
4 Results and discussion
4.1 Origins of organic matter
The kerogen type for the examined samples has been interpreted based on the results from maceral composition, Rock-Eval pyrolysis, and atomic ratios of isolated kerogen (i.e., H/C, O/C and C/N) (Qiao et al., 2020). The kerogen type was generally interpreted as type III kerogen, although there are large differences based on the indicators mentioned above (cf. Figure 7 in Qiao et al., 2020). So, it is necessary to use more parameters to interpret the OM origins.
The stable carbon isotope (δ13C) compositions of the saturated hydrocarbon fraction (δ13CSat.) in the analyzed J1b, J1s and J2x OM-rich shales vary from –28.95 to −29.97‰, −27.35‰ to −31.49‰, and −27.26‰ to −27.60‰, respectively; and of the aromatic fraction (δ13CAro.) from –25.47 to −28.46‰, −25.52‰ to −29.67‰, and −25.38‰ to −25.72‰, respectively. The δ13CSat. and δ13CAro. compositions of the investigated shales plotted on the Sofer (1984) diagram showing that all these extracts originated from shales that received predominantly terrestrial land plants (Figure 4). Another parameter, i.e., Canonical Variable (CV = − 2.53 × δ13CSat. + 2.22 × δ13CAro. − 11.65) (Sofer, 1984), can be used to discriminate OM from terrigenous and marine settings. Values of >0.47 indicate predominantly non-waxy terrigenous organic sources, whereas of <0.47 indicate more contribution from marine OM (Sofer, 1984; El Diasty et al., 2016). The calculated CV values for the studied samples ranging from −0.47 to −11.25 with 80% of >0.47 indicate that the OM was derived from terrestrial settings, and the samples below the threshold are likely to be affected by maturity (Collister and Wavrek, 1996) and caused by higher salinity mentioned later. Moreover, the CV values indicate the stratifications in water columns as well (Collister and Wavrek, 1996). The terrestrial OM can be further supported by the depleted δ13C values which are gradually increasing from the saturated hydrocarbon to the aromatic hydrocarbon, then to the resins ranging from −28.94‰ to −25.41‰ (avg. −26.68‰) and finally to the asphaltene ranging from −28.82‰ to −24.61‰ (avg. −26.31‰) (Galimov, 2006). The type III kerogen can be further supported by the relative concentrations of the asphaltenes and resins (from 3.2% to 92.4% and 39.4% on average, of EOM) compared to the concentrations of aliphatic and aromatic hydrocarbons (Figure 5).
FIGURE 4. δ13CSaturate vs δ13CAromatic for the extractable organic matter from the Jurassic organic-rich shale in the East Fukang Sag, Junggar Basin, China. The green line is the best fit separation for waxy and non-waxy hydrocarbons (Sofer, 1984).
FIGURE 5. Saturate/aromatic hydrocarbon ratios vs asphaltenes + resins concentrations showing the depositional setting, maturity and kerogen type of the Jurassic organic-rich shale in the East Fukang Sag, Junggar Basin, China.
Biomarkers, as indicators of parent sources of OM, have been widely used (Luo et al., 2016; Wu et al., 2022b; Zheng et al., 2022; Zhu et al., 2022). The distribution pattern of saturated hydrocarbons contains a lot of information on biological sources. n-alkanes with low carbon numbers (i.e., n-C12–C18) mainly originate from phytoplankton and algae (Meyers, 1997; Luo et al., 2016). Short-chain n-alkanes with relatively high concentrations of C17 or C18 typically originate from marine algae and cyanobacteria (Riboulleau et al., 2007; Sachse and Sachs, 2008). Middle-chain n-alkanes (n-C21–25) are sourced from aquatic higher plants in common (Ficken et al., 2000), especially with peak carbon of n-C23 and n-C25 alkanes (Huang et al., 1999) being inductive of aquatic pollen taxa, Nymphaea (Coetzee, 1967), Sphagnum moss species (Nichols et al., 2006; Bingham et al., 2010), fresh-water algae (Riboulleau et al., 2007). Furthermore, long-chain n-alkanes with obvious odd carbon predominance are generally input of higher plants (Eglinton and Calvin, 1967) and the high concentrations of C27, C29, and C31 n-alkanes are indicative of the land plant epicuticular waxes (Meyers, 1997). Based on the above indicative information, the parent material source of OM can be interpreted. The Paq values ranging from 0.36 to 0.90 (avg. 0.68) indicate aquatic macrophytes make an important contribution to OM (Ficken et al., 2000). The moderate to high WI values of 0.70–4.50 (avg. 1.91) in most samples indicate a substantial contribution of terrestrial OM. The CPI values of the investigated samples here are consistent with terrestrial OM input based on the consideration of the maturity stage. Additionally, the occurrence of branched alkanes indicates a contribution from bacteria to OM (Shiea et al., 1990). For example, the appearance of farnesane (i-C15) indicates the input of green sulfur bacteria (Summons and Powell, 1987). The concentrations of branched alkanes (e.g., i-C15/n-C13 are 0–2.57 with an average value of 0.33; i-C16/n-C14 are 0–2.52 with an average value of 0.52; i-C17/n-C15 are 0–2.89 with an average value of 0.24) indicate the contribution from bacterial was abundant.
However, it must be noticed that these results drawn from the distribution of n-alkanes distributions should be used with caution, because the longer the carbon chain, the easier it is to convert to shorter chains with increasing maturity and thus change its distribution pattern (Peters et al., 2005) and the biological source signal based on n-alkanes is not exclusive (Oros et al., 1999; Gonzales et al., 2020).
Steranes are mainly derived from higher plants (e.g., a high concentration of C29 steranes) and algae (e.g., a predominance of C27 steranes) (Huang and Meinschein 1979; Moldowan et al., 1986; Volkman 2003), and hopane sources are mainly from aerobic bacterial membranes (Ourisson and Rohmer, 1992; Peters et al., 2005). The low steranes/hopanes ratio ranging between 0.07 and 2.98 with an average value of 0.37 indicates a substantial input of bacterial biomass.
The ternary diagram of C27, C28 and C29 ααα 20R steranes distributions (Figure 6; Huang and Meinschein 1979) indicates that the OM of the J2x Formation sourced mainly from higher plants was deposited in a terrestrial environment, while the OM of the J1 formations (i.e., J1b and J1s formations) was a mixed OM derived from higher plants, bacteria and algae deposited under bay/estuary environments alternated with a terrestrial environment (Figure 6). Moreover, the presences of abundant TMPs and chrysene (Figure 3F), etc. are typically indicative of terrigenous higher plant input (Chaffee and Johns 1983; Chaffee and Fookes 1988).
FIGURE 6. Ternary diagram showing the distribution of C27, C28 and C29 steranes and the Jurassic organic-rich shales’ depositional environment in the East Fukang Sag, Junggar Basin, China (modified after Huang and Meinschein, 1979; Moldowan et al., 1985).
4.2 Paleodepositional environment
Based on the lithology assemblage (Figure 2), a typical lacustrine sedimental environment can be recognized. The lithology enriched in clay minerals was deposited in a non-restricted setting, which can be demonstrated by the high C27 diasteranes abundances compared to regular steranes, but low C21-22 steranes abundances compared to C27-29 steranes (Figure 7) (Wang et al., 2015; Qiao et al., 2021a; Zheng et al., 2022). Clay-rich lithology is further supported by the higher C30 hopane abundance compared to the lower C29 hopane abundance (Figure 3) with the C29/C30 hopane of 0.41–1.50 (0.68 on average) (Gürgey, 1999). This is consistent with the distribution of gradually regular decrease from C31 to C35 hopanes indicating clastic facies (Figure 3; Waseda and Nishita, 1998), the C26/C25 Tri (tricyclic terpane) (0.81–3.30 with an average value of 1.89) and C34/C35 hopane (1.02–4.35) ratios, low C22/C21 (0–1.08 with an average value of 0.25) and C24/C23 Tri ratios (0–6.21 with an average value of 0.63), as well as low HHI values (0–0.10) (Peters and Moldowan, 1991; Sinninghe Damsté et al., 1995; Peters et al., 2005) (Figure 8). Non-marine setting can be supported by the high ratios of C30 hopane/(20R steranes + C30 hopane) ranging between 0.18 and 0.83 (avg. 0.66) (Holba et al., 2003). The lacustrine depositional environment can be also supported by the low steranes abundances compared to hopanes in all formations (0–0.95 with an average value of 0.06) (Peters et al., 2005). Considering that steranes abundances would also be high in lacustrine settings which developed plenty of biomass inputs, the low steranes abundances in the studied area are consistent with the OM compositions discussed above.
FIGURE 7. Plot of C21–22/C27–29 steranes vs C27 diasteranes/regular steranes, showing the depositional setting of the Jurassic organic-rich shale in the East Fukang Sag, Junggar Basin, China (modified after Wang et al., 2015).
FIGURE 8. (A) C24/C23 vs C22/C21 tricyclic terpane and (B) C31R/C30 hopane vs C26/C25 tricyclic terpane of the Jurassic organic-rich shale in the East Fukang Sag, Junggar Basin, China (modified after Peters et al., 2005).
However, the parameter of C31 22R/C30 hopane ratios (0–0.52 with an average value of 0.25) (Figure 8B), which is inductive of marine situations at the situation of ratio >0.25 and lacustrine environments at of <0.25 (Peters et al., 2005), is inconsistent with the above discussion for the analyzed samples, which might be due to the paleosalinity conditions.
4.2.1 Paleosalinity conditions
Generally, salinity is more changeable in lake systems, which affects the community composition of the aquatic organism (Romero-Viana et al., 2012). Qiao et al. (2020) released some trace and rare earth elements to discuss the palaeosalinity conditions of the J2x, J1s and J1b formations based on the thresholds published by some early literature, which illustrated that the J1 and J2x formations were deposited under a fresh-water condition. However, some new thresholds have been proposed by Wei and Algeo (2020), where B/Ga is <3 in freshwater, with a value of 3–6 indicative of brackish, and transition from brackish to marine facies occurs at B/Ga ratio of 6; and Sr/Ba of <0.2 corresponds to freshwater, 0.2–0.5 to brackish, and >0.5 to marine facies. The new thresholds show a completely different conclusion, which indicates the most studied samples developed under freshwater conditions (65.8% and 68.5% based on Sr/Ba and B/Ga, respectively), some formed under brackish (23.3% and 15.1%) and a few under marine environments (11.0% and 16.4%).
The large variations of the Tris/C30 αβ hopane (0–5.88) and (pregnane + homopregnane)/steranes ratios (0–0.95), as well as the occasional appearance of β-Carotane, also deduce the lacustrine environment with changeable salinity (Kruge et al., 1990; Peters et al., 2005) (Figure 9A). The same result is further supported by 59% of the C30 hopane/(20R steranes + C30 hopane) ratios being smaller than 0.7 (Holba et al., 2003). The existence of gammacerane indicates the thermal and saline stratifications in water columns in lacustrine environments (Sinninghe Damsté et al., 1995). Gammacerane originates from tetrahymanol and is synthesized by bacterivorous ciliates that feed at the redox interface of the stratified water columns (Sinninghe Damsté et al., 1995). The wide range of gammacerane abundances with the gammacerane/C30 hopane ratios ranging between 0 and 0.3 is consistent with the above inferences on the salinity change and stratifications (e.g., the CV values in Section 4.1) in lacustrine environments. Additionally, the above discussion also proves that the thresholds proposed by Wei and Algeo (2020) are more reliable than those by earlier literature. The variation of salinity is consistent with the appearance of the brackish-water bivalve Waagenoperna in the J1b Formation of the Junggar Basin (Pan et al., 2013).
FIGURE 9. (A) Tricyclic terpanes/C30 hopane vs C21-22/C27-29 steranes and (B) Ph/n-C18 vs Pr/n-C17 (after Shanmugam 1985), showing the depositional condition of the Jurassic organic-rich shale in the East Fukang Sag, Junggar Basin, China.
4.2.2 Paleoredox conditions
Besides paleosalinity, OM preservation and paleoproductivity are affected by paleoredox situations (Katz, 2001). Pr/Ph ratio is an important parameter for paleoredox conditions (Didyk et al., 1978; Zhang et al., 2020; Wu et al., 2022b; Zheng et al., 2022). In general, Pr/Ph is >3 indicating oxic environments at the benthic water column with substantial contributions from higher plants, whereas Pr/Ph is <1 in anoxic situations with increasing input of algae (Didyk et al., 1978). The paleoenvironments with the shallower water column and more oxidation degree (e.g., marshes, wetlands, paralic etc.), the higher ratio of Pr/Ph. For the analyzed samples from the J2x Formation, most of them show the ratio of Pr/Ph being >3, indicating oxic environments. For the J1s samples, Pr/Ph ratios of 60% are between 1 and 3 and of 30% are <1, indicating suboxic environment conditions in most cases with some reducing environments. By contrast, Pr/Ph ratios of 66% from the J1b Formation are <1 and no ratios are >3 indicating least reducing situations (Didyk et al., 1978; Peters et al., 2005). Additionally, the oxic conditions of the water column for the J2x Formation are further supported by the plot of Pr/n-C17 vs Ph/n-C18 (Figure 9B). However, the bivariate plot of Pr/n-C17 vs Ph/n-C18 indicates the paleoredox conditions for the J1b were suboxic and J1s were reducing. In summary, the J2x Formation was deposited under oxic conditions, while J1 formations developed under suboxic and reducing environmental conditions. This result is completely inconsistent with the previous result based on elements (i.e., Ni/Co, V/Cr, and (Cu+Mo)/Zn) indicating the indiscriminately paleoredox conditions of oxic to dysoxic were prevailing during the deposition of these sediments (Qiao et al., 2020), which reaffirms the need for caution when using elements to identify paleoredox conditions (Algeo and Li, 2020; Algeo and Liu, 2020).
Previous studies have shown that high extended Tri ratios (ETR; (C28 Tris + C29 Tris)/Ts) are related to the upward shift of the photic zone euxinia caused by water level rise (Pagès et al., 2016), high salinity and strong reducing environments with low terrigenous input (Hao et al., 2009; 2011), or marine upwelling environment (Holba et al., 2001), and the moderate is indicative of an algal contribution of primary producers (Volk et al., 2005). C28 and C29 Tris can be identified in only two samples of the 15 samples from the J2x Formation (0.14 and 1.98), but they can be identified in half of the samples from the J1 formations (0.17–4.77 with an average value of 1.23). Summarizing the above discussions, the variations of ETR values were caused by the large variations of salinity and OM composition predominated by the terrestrial higher plant in all samples but J2x and J1 formations formed under different paleoredox conditions.
4.3 Thermal maturity of OM and hydrocarbon potential
Thermal maturity is an essential parameter for shale, which determines whether shale resources are available and what type of shale resources they are (e.g., shale-oil and shale-gas), and shows impacts on the diagenesis and porosity (Liu et al., 2022).
Some molecular parameters are widely used to evaluate thermal maturity (Holba et al., 2003; Volk et al., 2005; Zhu et al., 2012). The R configuration on the side chain of some compounds can be converted to S configuration with the increase of thermal maturity, and finally reached an equilibrium mixture of S and R configurations, thereby being regarded as maturity-dependent ratios, e.g., C31 and C32 homohopanes 22S/(22S + 22R) ratios as well as C29 ααα 20S/(20S + 20R) steranes. Moreover, the stability of a flat three-dimensional configuration (i.e., ααα configuration) is poor, which will transit to a more thermodynamically stable αββ configuration until ααα and αββ configurations reach an equilibrium ratio with the increase of maturity. So, C29 ββ/(ββ + αα) steranes can be regarded as a maturity-dependent parameter. Molecular maturity-related parameters are easily affected by conditions of sedimentary water columns. For example, ratios of 22S/(22S + 22R) hopanes and ββ/(ββ + αα) steranes show a higher maturity stage in immature extracts from hypersaline rocks (ten Haven et al., 1986; Rullkötter et al., 1994). This discrepancy can be observed in the Pleistocene hypersaline sediments in the Qaidam Basin, i.e., the obviously too high hopane and steranes maturity-dependent ratios in the definitely immature sediments (Qiao et al., 2021b). Moreover, sterane isomerization ratios are also affected by biodegradation and weathering (Peters et al., 2005). For the analyzed Jurassic shales, there is no clear weathering and biodegradation occurred. Moreover, the salinity of the water columns showed large variation, but it did not develop hypersaline conditions, so the molecular parameters are effective in the study area. A comparison of C31 and C32 homohopanes 22S/(22S + 22R) ratios being 0.45–0.63 and 0.29–0.59, respectively, indicate a thermal maturity between the early and main oil window (Figure 10A; Peters et al., 2005). The C29 ααα 20S/(20S + 20R) (0.23–0.50) vs ββ/(ββ + αα) (0.08–0.64) steranes plot shows similar maturity conditions (Figure 10B; Peters et al., 2005). It should be noted that two samples from J2x samples are immature based on Figure 10B, which might be because interference by co-eluting peaks can make the homohopane parameters invalid (Peterset al., 2005). The plots of C31 homohopanes 22S/(22S + 22R) ratio, C29 ααα 20S/(20S + 20R) steranes and C29 ββ/(ββ + αα) steranes vs depth (Figure 11) indicate that all the samples’ thermal maturity has entered oil windows and the molecular parameters appear to have reached the equilibrium value at around 3,500 m. Furthermore, the thermal maturity is further supported by the CPI (carbon preference index; Bray and Evans 1961) and OEP (odd-to-even predominance; Peters and Moldowan 1993) values. These two parameters are easily affected by the origin of OM because there is no clear odd-to-even predominance in the middle and long chains in the marine algae/saltwater algae. Considering the composition of the OM in the studied samples, the CPI of 1.01–1.43 and OEP of 0.83–1.38 are valid maturity parameters, indicating that most samples have entered into the oil window. The maturity that has entered the oil window is further confirmed by the high saturate/aromatic ratios (0.11–21.84) (Figure 5; Peters et al., 2005) and low to middle percentages of the resins compared to the saturated and aromatic hydrocarbons (from 2.3% to 46.5%, of EOM) (Ayinla et al., 2017). A similar maturity is interpreted by the MPs distribution (Radke, 1983) and the relative abundance of C26 and C28 20S triaromatic steroid (Thompson-Butler et al., 2019) (Figures 3E,H). The above results are consistent with the thermal maturity ranging from low mature and mature supported by Rock-Eval Tmax (426°C–468°C) and vitrinite reflectance (0.47–1.59%VRr) values released by Qiao et al. (2020).
FIGURE 10. Molecular indicators of thermal maturity by sterane isomerization for the Jurassic organic-rich shales in the East Fukang Sag, Junggar Basin, China. (A) C29 ααα 20S/(20S + 20R) vs C29 ββ/(ββ+αα) and (B) 22S/(22S + 22R) C31 vs C32 homohopane. equilibrium levels taken from Peters et al., 2005.
FIGURE 11. Plots of (A) C31 homohopanes 22S/(22S + 22R) ratio, (B) C29 ααα 20S/(20S + 20R) steranes and (C) C29 ββ/(ββ + αα) steranes vs depth of the Jurassic organic-rich shale in the East Fukang Sag, Junggar Basin, China.
Generally, the high PI values are caused by the early generation of hetero-compounds at the lower maturity (Curiale 1986), which are decreasing with the increase of thermal maturity (Lewan 1994). For the studied samples, a small number of samples have high PI values of > 0.4 with relatively lower Tmax values (Qiao et al., 2020), which are located in the area of the poorly-drained system where hydrocarbons can be impregnated in the coarser particle grained laminae in the shale (Jarvie 2012; Li et al., 2018). The relationship between PI and Tmax values (cf. Figure 4B in Qiao et al., 2020) indicates most analyzed samples are well-drained source rocks which expelled generated hydrocarbons efficiently to the various types of coarser grained siltstone closed intervals (Figure 2) (Raji et al., 2015). This assemblage of shale and siltstone is more typical of the hydrocarbon resources in the Chang 7 Member where coarser intervals (i.e., siltstone/muddy-siltstone) occurred in the direct vicinity within the shaly intervals act as tight-oil reservoirs and the shaly intervals are important shale-oil reservoirs (Qiao et al., 2021a). The economic hydrocarbon potential for the tight-oil reservoirs and shale-oil reservoirs can be further supported by the high oil saturation and the wide range of porosity from the EF 2 well (Figure 2).
4.4 Paleoclimate conditions
Kaolinite formed at temperatures higher than 15°C is commonly found in well-drained soils with high precipitation under humid tropical climates (Egger et al., 2002; John et al., 2012), whereas illite is generally formed in climates with very low weathering rates, such as cold regions and desert areas. Although sea level change and rainfall may also affect kaolinite deposition (e.g., Gibson et al., 2000), climate change is considered to be the primary control for clay minerals composition due to the lack of correlation between sea level change and kaolinite content (e.g., Robert and Chamley, 1991; Bolle and Adatte, 2001). Besides climate conditions, burial diagenesis affects clay mineral composition. Conversion occurs between different clay minerals due to the increase in formation pressure and geotemperature as well as the release of water between clay mineral layers and the migration of interlayer cations. Under shallow burial conditions, kaolinite and smectite exist in clay minerals, but these minerals disappear and are converted to illite and chlorite under deep burial conditions. Considering that the thermal maturity of the examined samples corresponds to the early stage of the intermediate diagenetic stage, the content of kaolinite is much greater than that of illite (Figure 12A), which is sufficient to indicate that the paleoclimate conditions of the study area were warm and humid, although the transition to illite has happened and the transition to chlorite has just begun at this stage as well as how much of these transitions have occurred is uncertain. Moreover, the kaolinite/illite ratio is significantly lower in the J2x samples compared to that in the J1 samples (Figure 12B), implying that the paleoclimate conditions were colder and drier during the J2x period, which is consistent with the results based on elemental Sr/Cu ratios (cf. Figure 6 in Qiao et al., 2020). This paleoclimatic change is also supported by the lithologic assemblages, i.e., the coal seam is mainly distributed in the J1b Formation and the lower part of the J2x Formation (Figure 2). The above inferences are consistent with the interglacial period that occurred during the Jurassic in NW China (Sellwood and Valdes, 1997). The same results were supported by sedimentologic, paleocurrent, and subsidence analyses (Hendrix et al., 1992), lithology characteristics and palynology (Ashraf et al., 2010), as well as sequence stratigraphy characteristics and fossil vertebrates (Eberth et al., 2001; Li et al., 2014).
FIGURE 12. (A) Clay minerals composition and (B) kaolinite/illite ratio distribution of the Jurassic organic-rich shale in the East Fukang Sag, Junggar Basin, China.
The change of paleoclimate in the formation of shale is mainly reflected in the water environment and biological composition. The colder and drier paleoclimate conditions may result in a smaller scale of the lake basin and shallower water depth during the J2x period. This resulted in the oxic benthic water column condition (Figure 9B and discussion in Section 4.2.2) and the proportion of terrestrial higher plants in the OM composition increased (Figure 6 and discussion in Section 4.1) during the J2x period in comparison to those during the J1 period. Another important indicator showing the J2x period was cooler than the J1 period is β-Carotane which occurs only in the J2x Formation (Jiang and Fowler, 1986; Fu et al., 1990; Koopmans et al., 1997) although β-Carotane is not very common.
The humid and warm climate conditions during the J1b, J1s and J2x periods of the study area were conducive to the development of the terrestrial higher plant but hard to form brackish water conditions. Even though the studied area became colder and drier during the J2x period, the change was not significant enough to cause the change of salinity in the water column and the vanish of terrestrial higher plants during the corresponding period (see Section 4.4 and cf; Qiao et al., 2020). Similar paleodepositional conditions can be observed in the Triassic Ordos Basin which developed a mixed OM composition and oxic to suboxic but freshwater conditions (Qiao et al., 2021a). Moreover, it is noteworthy that these salinities did not vary regularly in space and time, showing that they were not affected by climate change, so this variation was more likely due to seawater intrusion as proposed by Sha et al. (2011).
4.5 Enrichment mechanisms of organic-rich shales
Generally, the scale and enrichment degree of shales are controlled by the input and preservation condition of OM, which includes multiple factors, such as climate, paleontology growth, subsidence rate, as well as level and maturity of lake (Shen et al., 2015; Liu et al., 2021). All of these can be categorized into two groups, i.e., paleoproductivity and depositional conditions (Katz, 2001).
Based on the elemental evaluation proposed by Qiao et al. (2020), the investigated study area developed middle to high productivity. Moreover, the paleoproductivity during the J1 period was higher than that during the J2x period based on Ba concentrations (cf. Figure 6 in Qiao et al., 2020), but the TOC contents show similar characteristics vertically in all formations (Figure 2). This is because the Ba concentration only indicates the level of organic carbon fluxes in water columns, while the OM of the J2x is sourced mainly from terrestrial OM and the redox conditions were oxygen-rich conditions which were not prone to the OM preservation. Based on the relationship between the δ13Corg and TOC content, the OM accumulation was controlled by paleaoproductivity in the EF 2 well which is located at the margin of the sag, whereas the redox conditions exerted a primary control on the TOC contents in the samples from the EF 7 well located at the more central area of the sag (cf. Figure 13 in Qiao et al., 2020). This is because the basin margin was more prone to obtain OM from terrestrial higher plants, but the water was shallower and more oxidized due to a reduction in the size of the lake basin caused by cooler and drier paleoclimate conditions, which experienced strong oxygenolysis and were not in favor of the OM preservation. Although the substantial OM input from terrestrial inputs can promote the palaeoproductivity in the sag margin, this input was discontinuous resulting in the large variation of TOC content in the EF 2 well. Therefore, the large variations in the biotic palaeoproductivity from the terrestrial organisms were the material basis controlling the development of the organic-rich shales. By contrast, the redox conditions were more important for controlling OM presentation in the central area of the sag which was far from the terrestrial OM source with a small variation in TOC content (cf. Figure 13 in Qiao et al., 2020). In the central region of the basin, the paleoredox conditions of the benthic water column were deeper and more reductive and were less affected by the reduction of lake scale caused by the paleoclimate change. Considering the accumulation model deduced by Qiao et al. (2020), the paleoredox and salinity conditions as well as OM composition obtained in this study are more reasonable and supply more evidence.
5 Conclusion
The thermal maturity and origins of organic matter (OM), paleodepositional environment, paleoclimate condition, and factors controlling OM accumulation in the J1b, J1s and J2x lacustrine shales in the East Fukang Sag are reassessed by evaluating the organic geochemical characteristics of the OM. Some previous knowledge is updated, and some is further supported by more evidence.
The typical clay-rich shale developed under a lacustrine sedimental environment is recognized. The thermal maturity of these organic-rich shale has entered the oil window and the studied formations have economic hydrocarbon potential for the tight-oil reservoirs and shale-oil reservoirs. The clay minerals compositions and the distribution characteristics of β-Carotane indicate that the paleoclimate conditions of the study area were warm and humid from the Early to Middle Jurassic periods and were colder and drier after the Middle Jurassic period. The lacustrine environment developed changeable salinity ranging from freshwater to brackish, which is consistent with the reassessment from B/Ga and Sr/Ba ratios based on the update thresholds. The J2x formation was formed under oxic conditions, while J1b and J1s formations were developed under suboxic and reducing environmental conditions. For the OM composition, terrestrial OM and aquatic macrophytes made an important contribution and substantial contribution from bacteria, but the input from algae was limited. For the detail, the J2x Formation OM originated mainly from higher plants and was deposited in a terrestrial environment, while the OM of J1b and J1s formations was a mixed OM derived from higher plants and bacteria with little algae deposited under bay/estuary environments alternated with the terrestrial environment. Using elements to interpret paleoclimate and update elemental thresholds to evaluate paleosalinity conditions are effective, while using common elemental ratios to interpret paleoredox conditions and using Ba to evaluate paleoproductivity are invalid in the studied area.
Data availability statement
The datasets presented in this study can be found in online repositories. The names of the repository/repositories and accession number(s) can be found in the article/Supplementary Material.
Author contributions
JQ: Conception and design of study, data acquisition, analysis and/or interpretation of data, drafting the manuscript; QL: Project supervision and internal revision of the manuscript; YZ: Assisting in data interpretation and writing of the manuscript; DW and HC:XS: Data acquisition, assisting in data interpretation, revision of the manuscript. Methodology and Resources; LL and TZ: Resources.
Funding
The study was financially supported by the National Natural Science Foundation of China (NSFC), and the Science Foundation of China University of Petroleum, Beijing (Grants No. 42122016, and ZX20220074).
Acknowledgments
The authors thank all those who have helped us while writing this manuscript, especially the Xinjiang Oil field for the data supposition and reviewers for their constructive comments on the original version of this Manuscript.
Conflict of interest
TZ was employed by the company Xinjiang Oilfield Company.
The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Publisher’s note
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Keywords: lacustrine organic-rich shale, organic geochemistry, enrichment mechanisms, Fukang Sag, Junggar Basin
Citation: Qiao J, Luo Q, Zhang Y, Wang D, Cui H, Shang X, Liu L and Zhang T (2023) Formation conditions and enrichment mechanisms of the Jurassic lacustrine organic-rich shale in the East Fukang Sag, Junggar Basin, NW China: A reassessment based on organic geochemistry. Front. Earth Sci. 11:1086827. doi: 10.3389/feart.2023.1086827
Received: 01 November 2022; Accepted: 02 January 2023;
Published: 23 January 2023.
Edited by:
Bo Liu, Northeast Petroleum University, ChinaReviewed by:
Guangyou Zhu, Research Institute of Petroleum Exploration and Development (RIPED), ChinaHaiping Huang, China University of Geosciences, China
Copyright © 2023 Qiao, Luo, Zhang, Wang, Cui, Shang, Liu and Zhang. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Jinqi Qiao, jinqi.qiao@cup.edu.cn; Ye Zhang, Zhangye_sg@vip.163.com