Genetic Type and Source Analysis of Natural Gas in the Leikoupo Formation of the Sichuan Basin in China

The Middle Triassic Leikoupo Formation is largely extended through the Sichuan Basin, SW China. In this formation, several commercially exploited gas reservoirs have been discovered in western and central parts of the basin. Due to the complicated geochemical signatures of the natural gases in these reservoirs, there are contrasted interpretations about their sources, which hamper the evaluation and exploration for new gas resources in the area. To obtain complete understanding of the natural gas sources, the Leikoupo Formation gas reservoirs discovered so far in the Zhongba, Yuanba, Longgang, and Moxi gas fields were selected as the research object of this study. The genetic types and sources of the natural gases in the Leikoupo Formation are discussed based on gas geochemistry combined with their geological background. The natural gas in the top members of the Leikoupo Formation (T₂l⁴ or T₂l³) is partially originated from a humic kerogen contained in the source rocks from the overlying Upper Triassic Xujiahe Formation and from sapropel kerogen from the source rocks of the Leikoupo Formation itself. The natural gas of T₂l¹ member in the lower part of the Leikoupo Formation is mainly sapropel-type probably from the source rock of the Permian Wujiaping Formation, where the Permian Longtan Formation undergoes a phase change into the Wujiaping Formation The reversed δ¹³C₁ and δ¹³C₂ trend in the Leikoupo Formation of the Yuanba gas field is due to the more sapropelic source rocks and higher degree of maturity.

1 Introduction

The Middle Triassic Leikoupo Formation is the latest set of marine strata developed in the Sichuan Basin, China, which is not the main strata for oil and gas exploration, and the exploration and research conducted for the Leikoupo Formation is relatively low. Back in the 1970s, small-scale gas pools were discovered in this set of strata, for example, the third member (T₂l³) of the Leikoupo Formation in the Zhongba gas field in NW Sichuan (Qin et al., 2007), and the first member (T₂l¹) of the Leikoupo Formation in the Moxi gas field in central Sichuan. With the increasing natural gas exploration, commercial gas reservoirs have been found in the fourth section (T₂l⁴) of the Leikoupo Formation in the Longgang and Yuanba gas fields successively in this century, showing that the Leikoupo Formation has good potential for gas exploration. Since the Leikoupo Formation is dominated by evaporative platform facies as a whole, and evaporites mainly composed of gypsum and dolomite are deposited, it is doubtful whether the Leikoupo Formation formed in such an environment can develop effective source rocks. In addition, the geochemical characteristics of natural gas in the Leikoupo Formation are complex, and the types of natural gas origin are diverse. It is difficult to identify the gas sources, and there are different opinions on the source of natural gas. For example, in the Leikoupo Formation in the Zhongba gas field in western Sichuan, it was believed that all natural gas came from the underlying Permian hydrocarbon source rocks (Dai, 1980). It was also believed that the gas came from biogenic limestone and mudstone of the Leikoupo Formation (Li, 1993; Qin et al., 2007). Some studies suggested that the gas came from Permian sapropel source rock, mixed with a small amount of gas from coal measures (Liao et al., 2013), and some even thought that the gas mainly came from overlying coal measures (Wang, et al., 1989; Zheng, et al., 1990). In the central Sichuan Basin, recoverable gas reservoirs have been found in both the T₂l⁴ and T₂l¹ members of the Leikoupo Formation, but the gas geochemical characteristics differ significantly between the reservoirs, and the gas source is highly controversial (Huang, 2014; Liu, et al., 2014; Zhou, et al., 2015; Liu, et al., 2019). Even within the T₂l⁴ member, the gas’ geochemical signatures are highly variable; the gas indicated to be not only humic-type gas but also sapropel-type, and it is difficult to explain the source of gas.

In this study, the gas reservoirs of the Leikoupo Formation in the Zhongba, Moxi, Longgang, and Yuanba gas fields that have been discovered so far are systematically analyzed using natural gas geochemical methods. The source of natural gas has been elucidated based on the comparative study of Triassic and Permian natural gas types and their source rocks, which in turn provides a basis for natural gas exploration in the Leikoupo Formation.

2 Geological Background

The Indo-Chinese early episodic movement at the end of the Middle Triassic made the central Sichuan area rise to land, the seawater withdrew, and the large inland lake basin began to appear, which was an important turning period from marine sedimentation to lacustrine sedimentation in the Sichuan Basin as it ended the deposition of the carbonate platform in Sichuan. The uplift of the Sichuan Basin suffered from denudation, forming the erosion surface at the top of the Middle Triassic Leikoupo Formation. Since the Late Triassic, it has received continental deposits and developed multiple sets of coal-measure source rocks and multiple sets of interbedded sedimentary assemblages of sandstones.

2.1 Strata

There are many oil- and gas-bearing layers in the Sichuan Basin. This study focuses on the gas reservoir in the Leikoupo Formation. The related layers span the Triassic and the upper Permian. The strata from top to bottom are the Upper Triassic Xujiahe Formation (T₃x), Middle Triassic Leikoupo Formation (T₂1), Lower Triassic Jialingjiang Formation (T₁J) and Feixianguan Formation (T₁f), and Upper Permian Changxing Formation (P₃ch) and Longtan Formation (P₃1) (Figure 1).

FIGURE 1

FIGURE 1. Distribution of main gas fields and the Permian–Triassic petroleum system in the central and western Sichuan Basin.

The Xujiahe Formation is a fluvial–swamp–lacustrine deposit developed in a humid environment (Luo, 1983, 2011; Li, 2011). Several sets of coal-measure source rocks and sandstone reservoirs are developed. The coal-measure source rocks and sandstones were stacked on top of each other. The Xujiahe Formation is subdivided into T₃x¹ to T₃x⁶ members from bottom to top, in which T₃x¹, T₃x³, and T₃x⁵ are mainly coal-measure sources, and the organic matter is mainly kerogen-Ⅲ type, which is a gas dominated source rock. The T₃x², T₃x⁴, and T₃x⁶ members are dominated by sandstone (Wang, et al., 1997; Yang, et al., 2005; Li et al., 2010) and are good reservoirs for gas storage.

The top of the Leikoupo Formation (T₂l) suffered from dissolution and contact with the overlying Xujiahe Formation in parallel unconformity. The T₂l is mainly composed of grayish-white medium-thick microcrystalline dolomite, argillaceous dolomite, and gray dolomite, with light gray gypsum and thin gray-black shale, which is a high-quality caprock in the whole area, in which the gray-black shale can be used as a hydrocarbon source rock. It is subdivided into T₂l¹ to T₂l⁴ members from bottom to top, among which the natural gas reservoirs have been discovered in T₂l¹, T₂l³, and T₂l⁴ members.

The Jialingjiang Formation (T₁j) is composed of gray micrite limestone and dolomite interbedded with a gypsum layer, dolomitic gypsum, and argillaceous dolomite, which is not only a high-quality caprock in the whole area but also a gas reservoir in the Jialingjiang Formation. The top of the Feixianguan Formation (T₁f) consists of mudstone, dolomitic mudstone, gypsum, dolomicrite, micrite, and marlstone. The middle and lower part of the Feixianguan Formation is karst oolitic dolomite and limestone, which has good porosity and permeability and a regional high-quality reservoir rock (Wen, et al., 2012; Zhang, et al., 2013; Zhu, et al., 2013).

The Upper Permian (P₃) includes the Changxing Formation (P₃ch) and the Longtan Formation (P₃1) from top to bottom. The Changxing Formation is mainly composed of bioclastic micrite limestone, reef limestone, and dolomite, which is also an important reservoir in central Sichuan (Peng, et al., 2011). The Longtan Formation is mainly composed of marine–continental transitional coal measures and marine biological limestone, which is an important regional hydrocarbon source rock series and the main source rock of Changxing and Feixianguan gas reservoirs such as Longgang and Yuanba gas fields. It should be pointed out that the coal-measure source rocks of the Longtan Formation have undergone phase transformation in some areas and become marine source rocks of the Wujiaping Formation (P₃w), and the hydrocarbon-generating material changed from humic to sapropel-type.

2.2 Gas Reservoir Types

The Leikoupo Formation gas reservoirs include T₂l¹, T₂l³, and T₂l⁴ members. A weathering crust and a karst reservoir are developed at the top of the Leikoupo Formation, and their distribution are controlled by lithology and paleogeomorphology of exposed strata at the top (Bian, et al., 2019). The T₂l³ gas reservoir of the Leikoupo Formation in the Zhongba gas field is distributed in the dolomite layer, which is an anticline reservoir type. The top is in an unconformable contact with the overlying Xujiahe Formation, missing the T₂l⁴ member (Zeng, et al., 2007). The top surface of the Leikoupo Formation in the Yuanba gas field was affected by denudation and karstification, and a dolomite karst reservoir was formed in the T₂l⁴ member. The reservoir is controlled by paleogeomorphology and has strong lateral heterogeneity (Fan, 2014), there is no unified gas–water interface, and natural gas tends to be distributed in structural highs (Liu, et al., 2019); therefore, the reservoir is a karst-controlled structural and lithologic gas reservoir. The reservoir of the T₂l⁴ in the Longgang gas field is related to Indosinian denudation and karstification (Yang, et al., 2014), and the natural gas between different wells in the lateral direction is quite different, with obvious heterogeneity, which is a structural and lithologic gas reservoir. The T₂l¹ gas reservoir is currently mainly discovered in the Moxi gas field. This reservoir has a large trap area and is an anticline porous carbonate gas reservoir with a high degree of fullness. It has a unified gas–water interface and is a monolithic gas reservoir.

2.3 Possible Source Rocks

The reason why it is difficult to judge the source of natural gas in the Leikoupo Formation is that there are several sets of different types of source rocks developed in the Leikoupo Formation and it’s overly and underlying strata, which may provide a gas source for the Leikoupo gas reservoirs under appropriate geological conditions. This increases the difficulty for identification of Leikoupo gas sources.

The natural gas generated by coal-measure source rocks of the Xujiahe Formation has formed many large- and medium-sized gas fields in the Sichuan Basin. The source rocks directly cover the unconformities of the Leikoupo Formation and might partly provide gas for the karst reservoirs of the Leikoupo Formation.

The Jialingjiang, Feixianguan, and Changxing formations under the Leikoupo Formation did not develop source rocks. Under the Changxing Formation, the marine–terrestrial transitional coal-measure source rocks developed in the Formation had acted as a source rock for many large gas reservoirs in Changxing and Feixianguan formations of Longgang, Yuanba, and Puguang gas fields (Hao, et al., 2008; Wu et al., 2015; Qin, et al., 2016a; Deng, et al., 2018). If conditions permitted, it might also be possible to indirectly supply gas sources to the Leikoupo gas reservoir through the Changxing, Feixianguan, and Jialingjiang formations.

The Leikoupo Formation was formed in a salinized evaporation environment. Many researchers questioned that such an environment could form high-quality source rocks. Theoretically, such a saline environment has weak hydrodynamics, limited seawater circulation, high salinity, and alternating deposition of gypsum salt and carbonate rocks, which is conducive to the preservation of organic matter, and some of the strata can develop high-quality source rocks. Early studies believed that the Leikoupo Formation in the western Sichuan Basin was an algae-rich carbonate rock deposited in deep-water lagoon facies on a confined-evaporative platform and had favorable conditions for forming the main source rock of large- and medium-sized gas fields (Xu et al., 2013). The gypsum-bearing carbonate samples of the Leikoupo Formation in the western Sichuan Basin have relatively high TOC, and the gypsum-dolomite flat and gypsum-bearing lagoon facies with more evaporative platform facies are deposited, which are favorable sedimentary facies belts and lithologic assemblages for the development of high-quality source rocks (Yang, 2016; Wang, et al., 2018b). Other studies have concluded that the TOC of organic-rich shale in the Leikoupo Formation in the Sichuan Basin is 0.49%–1.08%, with an average of 0.77%, and the Ro values are 2.36%–2.40% (Sun, et al., 2021). According to the evaluation standard of a highly mature source rock (Dai, et al., 2008), it is evaluated as a high-quality source rock. The source rock was formed in a dry heat, salt water, and anoxic environment. Drilling revealed that the actual drilling thickness of the Leikoupo Formation in the central and northern Sichuan area is 960 m, of which the T₂l³ member is the most likely the source rock with a thickness of 530 m, and the lithology is argillaceous limestone, micrite limestone, organic-rich shale rock, salt rock, and gypsum. The T₂l¹, T₂l², and T₂l⁴ members are dominated by dolomite and gypsum rock, and no source rocks have been found (Sun, et al., 2021).

In fact, it is not uncommon to form source rocks in evaporative environments. In both the Bohai Bay Basin and the tertiary of the Qaidam Basin, the symbiotic phenomenon of evaporite and the source rock had been found (Jin, et al., 2006). In the Junggar Basin (Yu, et al., 2018), Polish Basin (Krzywiec, et al., 2017), Mexico Basin (Xie, et al., 2019), and West Texas–New Mexico (Hussain, et al., 1991), source rocks had been found in an evaporative environment.

3 Sampling and Analytical Methods

3.1 Sample Collection

Natural gas samples were taken from the Xujiahe, Leikoupo, Jialingjiang, and Changxing formations in the central Sichuan Basin. To eliminate the interferences of external factors and ensure representativeness of the natural gas in these reservoirs, all samples were collected from wells with long-term normal production without application of de-foaming or any other chemical agents recently.

Gas samples from the reservoirs were taken at the wellheads by using double valve steel cylinders. To take such samples, the pressure gauge was dismantled before connecting the steel cylinder with the sampling tubing. Prior to taking samples, wellhead natural gas was used to flush the steel cylinder thoroughly for about 3 min. The sampling steel cylinder was then filled with natural gas equilibrated to the wellhead pressure.

3.2 Analytical Methods

Natural gas compositions were determined using an Agilent 6890N gas chromatograph (GC) with He and N₂ as the carrier gases. Double thermal conductivity detectors (TCD) and a 30 m × 0.25 mm × 0.25 μm quartz capillary column were used. The inlet temperature was 150 °C, and the TCD temperature was 200 °C. The initial oven temperature was maintained at 40 °C for 7.5 min isothermally, then rose from 40 °C to 90 °C at 15 °C/min, and finally rose from 90 °C to 180 °C at 6 °C/min.

An on-line analysis was conducted for the measurement of carbon isotopic compositions with a MAT 253 gas isotopic mass spectrometer. Natural gas samples were separated to methane, ethane, propane, butane, and CO₂ using the chromatography column of an SRI 8610C gas chromatograph, which were then transferred into a combustion furnace by the carrier gas (He) and oxidized into CO₂ by CuO at 850°C. All of the converted species were transferred by the carrier gas (He) into MS to measure the isotopic compositions. A dual inlet analysis was performed with the international measurement standard of NBS-19 CO₂ (δ¹³CVPDB=1.95 ± 0.04‰, International Atomic Energy Agency, 1995), and the stable carbon isotopic values were reported in the δ notation in per mil (‰) relative to the Peedee belemnite standard (VPDB). Reproducibility and accuracy were estimated to be ± 0.2‰ with respect to the VPDB standard.

4 Analytical Results

4.1 Natural Gas Components

The hydrocarbon gas contents of the 38 samples in this study range from 60.19% to 99.71%, with an average of 92.77%. Samples also contain a small amount of N₂, CO₂, and H₂S (Table 1). A small number of samples have N₂ content exceeding 10%; other samples have N₂ content of 0–3.8%, with an average of 1.01%. Most of the samples have low CO₂ content, less than 5%. A few samples have higher CO₂ content. The marine carbonate rocks in the reservoirs are accompanied by gypsum salt. This results in the gas reservoirs generally containing H₂S. Most of the natural gas containing H₂S in the world is distributed in such type of strata, and it is considered to be formed by TSR action (Krouse, et al., 1988; Worden, et al., 1995; Machel, 2001; Cross et al., 2004). The content of heavy hydrocarbon gas such as ethane in the hydrocarbon gas is very low, and the dry coefficient (C₁/C₁₊) of natural gas is very high, ranging from 0.940 to 0.998, with an average of 0.983. Taking more than 0.95 as the criterion for dry gas, all the natural gas in the Leikoupo Formation is dry gas. Among them, the T₂l¹ gas reservoir in the Moxi gas field has the highest dry coefficient, with an average of 0.998, and the T₂l³ gas reservoir in the Zhongba gas field is the lowest, with an average of 0.97. The T₂l⁴ gas reservoirs in the Longgang and Yuanba gas fields are 0.971 and 0.991, respectively. Although both belong to T₂l⁴ gas reservoir, the dry coefficient of the Yuanba gas field is slightly larger than that of the Longgang gas field, reflecting the difference in the maturity of the source rocks.

TABLE 1

TABLE 1. Composition and isotopic data of Permian and Triassic natural gas in the central Sichuan Basin.

The natural gas in the upper and lower strata of the Leikoupo Formation is mainly hydrocarbon gas, the content of non-hydrocarbon gas is relatively low, and there are obvious differences in natural gas components between different strata.

The most important feature of natural gas in the Xujiahe Formation is that it does not contain H₂S; the content of N₂ is 0−16.5%, with an average of 1.36%, and the content of CO₂ is 0−8.13%, with an average of 0.78%. The content of ethane and other heavy hydrocarbon gas in alkane gas varies greatly for different gas reservoirs. The content of heavy hydrocarbon in the Zhongba gas field and the Longgang gas field is similar. The content in the Zhongba gas field and the Longgang gas field is between 2.22% and 11.37%, respectively, with an average of 7.32%, and the dry coefficient is between 0.89% and 0.98%, with an average of 0.92. There are both dry gas and wet gas in natural gas, indicating that the characteristics of gas source rocks are more complex. The content of heavy hydrocarbon gas in the Yuanba gas field is not only relatively low but also relatively concentrated, 0.71%–2.82%, with an average of 1.40%, and the dry coefficient is 0.97–0.99, with an average of 0.99. This shows that the source rock characteristics of natural gas in the Yuanba gas field are located under and adjacent to the T₂l¹ gas reservoir. The composition characteristics of natural gas are highly consistent with that of the T₂l¹ gas reservoir, and the dry coefficient of natural gas is close to 1.0%. The average content of N₂ is 1.1% and that of CO₂ is 0.2% (Table 1).

The gas reservoirs of Feixuan and Changxing formations under the Jialingjiang Formation have the same source of natural gas (Qin, et al., 2016a), and the geochemical characteristics of natural gas are completely the same. The natural gas dry coefficient is close to 1; contains higher H₂S, nitrogen, and carbon dioxide content of most samples less than 5%; and also there are some samples have high content (Table 1).

4.2 Carbon Isotope of Natural Gas

The carbon isotopes of natural gas in the Leikoupo Formation are generally less negative, and the overall characteristics are that the δ¹³C₁ value is relative concentrated, ranging from −38.4‰ to −31.7‰, with an average of −35.4%, but the δ¹³C₂ values vary widely, ranging from −36.7‰ to −25.1‰, with an average of −31.4‰. As the propane content is very low, only part of the samples were detected, with the δ¹³C₃ values ranging from −33.4‰ to −22.1‰, with an average of −26.9‰.

The carbon isotopes of different gas reservoirs are obviously different. The carbon isotope values of the T₂l¹ gas reservoir in the Moxi gas field are the most concentrated, with δ¹³C₁ ranging from −35.8‰ to −32.8‰, with an average of −34.4‰, and δ¹³C₂ ranging from −33.8‰ to −29.7‰, with an average of −32.3‰. Although the δ¹³C₁ values are concentrated in the T₂l³ gas reservoir in the Zhongba gas field and the T₂l⁴ gas reservoir in Longgang and Yuanba gas fields, the range of the δ¹³C₂ value is widely distributed, ranging from −36.7‰ to −25.1‰. The carbon isotope characteristics of natural gas in the Jialingjiang Formation are consistent with those of the T₂l¹ reservoir, with δ¹³C₁ ranging from −34.8‰ to −32.4‰, with an average of −34.1‰, and δ¹³C₂ ranging from −34.6‰ to −32.9‰, with an average of −33.7‰.

The δ¹³C₁ of Changxing and Feixianguan formations in Yuanba and Longgang fields are the least negative in this area, and the variation range is relatively narrow, indicating the relatively consistent gas source rocks. The δ¹³C₁ ranges from −31‰ to −27.8‰, with an average of −29.2‰, and δ¹³C₂ ranges from −29.7‰ to −21.7‰, with an average of −25.8‰ (Table 1).

The δ¹³C₁ of the Xujiahe Formation gas reservoir ranges from −42.2‰ to −30.0‰, with an average of −34.7‰, and the δ¹³C₂ ranges from −35.4‰ to −20.8‰, with an average of −26.3‰. The carbon isotopes of natural gas vary widely, especially the ethane carbon isotopes that reflect the genetic types of natural gas. The natural gas of the Xujiahe Formation mainly comes from its own coal-measure source rocks, and its carbon isotopes vary greatly, which reflects that the source rock type of natural gas may not be single.

In addition, the natural gas in Leikoupo and Xujiahe gas reservoirs in the Yuanba gas field show the inversion of δ¹³C₁ and δ¹³C₂, that is, δ¹³C₁ > δ¹³C₂ (Table 1; Figure 2).

FIGURE 2

FIGURE 2. Comparison of carbon isotope characteristics of Permian–Triassic natural gas in the Sichuan Basin.

5 Genetic Types of Natural Gas

According to the carbon isotope distribution chart, it can be seen that among the natural gas in the Leikoupo Formation, the Longgang gas field is the most negative, followed by the Zhongba gas field. Yuanba and Moxi gas fields are relatively less negative (Figure 2). The source maturity of natural gas in the Leikoupo Formation of Longgang, Zhongba, Yuanba, and Moxi gas fields increases sequentially. The gas samples of T₁j and T₂l¹ gas reservoirs in the Moxi gas field completely overlap in Whiticar’s chart. The natural gas of Changxing and Feixiangguan formations in Yuanba and Longgang gas fields also fall in the same area, and the maturity of their source rocks are much higher than that of the Leikoupo gas reservoir (Figure 3). In order to judge the genetic type of natural gas more precisely, this study adopts the identification standard of genetic type of natural gas proposed by Dai, that is, the value of δ¹³C₂ more negative than −28.8‰ indicate the sapropel-type gas (Dai, 1993).

FIGURE 3

FIGURE 3. Identification of natural gas from the Leikoupo Formation in the Sichuan Basin using Whiticar’ identification Chart [(modified after Whiticar (1999)].

It can be seen from Table 1 that the δ¹³C₂ values of natural gas in the T₂l¹ reservoir of the Moxi gas field are more negative than −28.8‰, the genetic type is relatively simple, and all samples are sapropel gas. Among the three natural gas samples of the T₂l³ member in the Zhongba gas field, two samples are sapropel gas and one is humic. The genesis of natural gas in the T₂l⁴ reservoirs of Longgang and Yuanba gas fields is complicated; some samples are humic gas and some are sapropel-type, and the heterogeneity of the gas reservoir is very obvious. Half of the natural gas samples of the T₂l⁴ gas reservoir in the Longgang gas field are humic-type, while only a few samples of the T₂l⁴ gas reservoir in the Yuanba gas field are humic-type, and the natural gas is mainly sapropel-type (Figure 4). The carbon isotope of alkane gas series can better reflect the overall appearance of natural gas. Half of the samples of the T₂l⁴ gas reservoir in the Longgang gas field are humic-type and the other half are sapropel-type, while the gas samples of the T₂l⁴ gas reservoir in the Yuanba gas field are mainly sapropel-type, and only a few are humic gas (Figure 5).

FIGURE 4

FIGURE 4. Genetic types of natural gas in the T₂l⁴ reservoir of the Sichuan Basin.

FIGURE 5

FIGURE 5. Comparison of δ¹³C of natural gas between the T₂l⁴ reservoir and the P₃ch-T₁f reservoirs of the Sichuan Basin.

6 Discussion on Natural Gas Sources

6.1 The T₂l⁴ Gas Reservoir

The paleokarst on the top of the Leikoupo Formation developed and formed a good karst reservoir, which showed an unconformable contact with the coal-measure source rocks of the overlying Xujiahe Formation (Song, et al., 2012; Wang, et al., 2018a). Some corrosion ditches are formed in the Leikoupo Formation, and the corrosion ditches will be filled by the Xujiahe Formation. Theoretically, the natural gas generated by the source rocks of the Xujiahe Formation has the opportunity to migrate to the top reservoir of the Leikoupo Formation; therefore, the samples showing humic-type in T₂l⁴ reservoir should come from the source rocks of the Xujiahe Formation.

It is researched that there is a close relationship between the δ¹³C₂ values and the C₂H₆ content in the T₂l⁴ reservoir of Longgang and Yuanba gas fields. The higher the ethane content, the less negative of the carbon isotope, showing the characteristics of humic gas. Taking the Longgang gas field as an example, the samples with ethane content more than 2% in the T₂l⁴ reservoir are humic gas, and on the contrary, those with the ethane content less than 2% are sapropel gas. A similar situation has occurred in the Yuanba gas field. Because the maturity of the source rocks is higher than that of the Longgang gas field, the ethane content is generally lower than that of the Longgang, but the δ¹³C₂ also tends to become less negative with the increase of the ethane content. The ethane content of several humic-type gas samples in T₂l⁴ is more than 1%. The ethane content of sapropel gas samples is less than 1% (Figure 4). The δ¹³C₂ value can best reflect the type of source rock, and the content of ethane can often reflect the content of heavy hydrocarbon gas, which indirectly reflects the dry coefficient (or humidity coefficient) of natural gas; the higher value of the ethane content, the lower the dry coefficient (high humidity coefficient). The humidity coefficient is related to the maturity of source rocks. For the same type of source rocks, the smaller the humidity coefficient, the higher the maturity of source rocks (Dai, et al., 2016b). Under the same degree of evolution, different types of source rocks have different dry coefficients, the sapropel-type is lower than humic-type. The ethane content of sapropel gas is less than that of sapropel gas in T₂l⁴, indicating that the maturity of sapropel gas of hydrocarbon source rocks is higher than that of humic gas.

According to the carbon isotope of the alkane gas series of the T₂l⁴, there are obvious differences in carbon isotopes of heavy hydrocarbons such as ethane between sapropel and humic gas; however, there is no obvious difference in the δ¹³C₁ values (Figure 5). Based on this, it is concluded that the sapropel gas in T₂l⁴ can only come from the source rocks of the Leikoupo Formation or other underlying strata, mainly sapropel organic matter. Due to the fact that the δ¹³C₁ value generated by sapropelic source rocks is more negative than that generated by humic source rocks under the same maturity, the δ¹³C₂ value is highly related to the type of organic matter and does not change obviously with the increase of the maturity of source rocks, and the genetic type of natural gas is therefore often identified according to the ethane carbon isotope.

As the Xujiahe Formation is the first terrestrial strata deposited after the end of marine sedimentation in the Sichuan Basin, in addition to humic source rocks, the T₃x¹ member may also develop marine sapropel source rocks at some local area. It is unlikely that the sapropel gas in the T₂l⁴ reservoir come from the sapropel source rocks that may undergo phase transformation corresponding to the T₃x¹ member in contact with it. If the sapropel gas in the T₂l⁴ comes from the sapropel source rock in the T₃x¹ member, the maturity of this source rock should be similar to other humic hydrocarbon source rocks in the T₃x¹. As mentioned before, the δ¹³C₁ from rocks with the same maturity should be lighter than those from humic source rocks. In fact, the δ¹³C₁ of sapropel and humic gas in T₂l⁴ are similar, but the δ¹³C₂ is quite different (Figure 5). The ethane content of sapropel gas in the T₂l⁴ reservoir is less than that of humic gas (Figure 4). Therefore, it is judged that the sapropel gas in T₂l⁴ comes from source rocks with higher maturity than the source rocks in the T₃x¹ member.

It is not possible that the sapropel gas in T₂l⁴ came from the source rocks of the Longtan Formation below. This is because the hydrocarbon source rocks of the Longtan Formation and the T₂l⁴ reservoir are separated by multiple sets of gypsum strata from the Jialingjiang Formation and T₂l¹ to T₂l³ members, and there are many sealing layers, making it difficult for natural gas to migrate to the T₂l⁴ reservoir. In addition, the natural gas from the Changxing and Feixianguan formations in Longgang and Yuanba gas fields all come from coal-measure source rock of the Longtan Formation; the carbon isotopes of methane and ethane are much less negative, and their characteristics are very different from those in T₂l⁴ reservoirs, uncorrelated with the gas in T₂l⁴ reservoir (Figures 3, 5). Collectively, it is judged that the sapropel gas in T₂l⁴ should come from the source rocks developed in the T₂l³, and the humic gas comes from the Xujiahe coal-measure source rock.

6.2 The T₂l³ Gas Reservoir

The forming condition of T₂l³ gas reservoir is similar to that of the T₂l⁴, in which the humic gas comes from the overlying Xujiahe Formation source rocks and the sapropel gas comes from the T₂l³ source rocks. In this study, the T₂l³ gas reservoir occurs in the Zhongba gas field, where the T₂l⁴ member is depleted and the T₂l³ section is in unconformity contact with the overlying Xujiahe Formation. The T₃x² gas reservoir develops above the T₃x² member in the gas field. The δ¹³C₁ of the gases in T₂l³ and T₃x² reservoirs are similar, with the former averaging −37‰ and the latter −36‰, but δ¹³C₂ are more different, with the Leikoupo Formation being more negative, averaging −29.7‰, and the T₃x² averaging −24.7‰, both of which are from different hydrocarbon source rocks. The T₂l³ itself has source rock, and the sapropel-type gas should come from the T₂x³ member source rock.

6.3 The T₂l¹ Gas Reservoir

In this study, all gas data of T₂l¹ come from the Moxi gas field, where the T₂l¹ gas reservoir is adjacent to the underlying Jialingjiang gas reservoir, and its geochemical characteristics are highly consistent with the natural gas in the Jialingjiang Formation based on the analysis of the samples in this study (Figures 2, 3, 6). The gas in both reservoirs should be from the same source, but it is difficult to determine which set of hydrocarbon source rocks the gas comes from. First, it is impossible for the gas to come from the coal-measure source rocks of the Xujiahe Formation because the gas characteristics of the T₂l¹ do not match the humic gas and there are effective interlayers between the Xujiahe Formation and T₂l¹, T₂l², T₂l³, and T₂l⁴ members, and it is difficult for the gas of the Xujiahe Formation to traverse downward through the multilayered gypsum rocks to reach the T₂l¹ reservoir.

FIGURE 6

FIGURE 6. Comparison of δ¹³C₁ and δ¹³C₂ in natural gas between the Leikoupo Formation and underlying gas reservoirs.

Comparing the isotopic data of typical sapropel gas samples from the T₂l⁴ section of the Longgang and Yuanba gas fields with the T₂l¹ gas reservoir, it is found that the T₂l¹ gas is closer to the sapropel gas of the T₂l⁴ reservoir in Yuanba. The difference is that most of the sapropel gas samples from the T₂l⁴ reservoir in Yuanba show carbon isotope inversion, while the carbon isotopes of gas from the T₂l¹ reservoir in Moxi do not. The δ¹³C₂ (average −32.3‰) is significantly less negative than that of sapropel gas (average 35.3‰) in the T₂l⁴ gas reservoir in Yuanba (Figure 7), and the source rock may be relatively humic. Although there are some similarities between the carbon isotopes of T₂l¹ gas and T₂l⁴, we cannot suggest that T₂l¹ gas may also come from T₂l³ hydrocarbon source rocks because the direct caprock of the T₂l¹ gas reservoir is the gypsum layer and gypsum dolomite above the gas reservoir. There are three layers of anhydrite layers with a total thickness of about 5 m on the gas reservoir, and 20 layers of anhydrite and gypsum dolomite are sandwiched up together with the T₂l¹ member, with a thickness of 160 m, which together constitute a good direct cover for the T₂l¹ gas reservoir (Dai, et al., 1996). Therefore, it is difficult for natural gas in the T₂l³ member to migrate down to the T₂l¹ reservoir across such a thick high-quality caprock.

FIGURE 7

FIGURE 7. Comparison of δ¹³C₁ and δ¹³C₂ of natural gas in the T₂l¹ reservoir with T₂l⁴, P₃ch and T₁f reservoirs.

Earlier studies suggested that the natural gas in the T₂l¹ gas reservoir of the Moxi gas field was mainly from the coal-measure source rock of the Longtan Formation based on the less negative of δ¹³C₂ value in some drilled wells (Wang, et al., 1998). However, the average δ¹³C₂ value of T₂l¹ gas is −32.3‰, which is typical of sapropel gas (Figure 6). Its methane and ethane carbon isotopes are very different from the natural gas from the Longtan Formation coal-measure source rocks in the Changxing and Feixianguan formation gas reservoirs of the Longgang and Yuanba gas fields, and the carbon isotopes of the Changxing and Feixianguan natural gas are much less negative (Figure 7). Therefore, the natural gas in T₂l¹ gas reservoir does not come from the coal-measure rocks of the Longtan Formation. However, the coal-measure hydrocarbon source rocks of the Longtan Formation would have undergone a phase change in some areas of the Sichuan Basin and become marine hydrocarbon source rocks of the Wujiaping Formation (the Upper Permian), with a shift in organic matter type from humic to sapropelic. Compared with the coal measures of the Longtan Formation, the carbon isotope of the natural gas generated by the source rocks of the Wujiaping Formation would be relatively more negative, which can completely match the natural gas of the T₂l¹ member. Therefore, it is believed that the natural gas from the T₂l¹ member of the Moxi gas field comes from source rocks of the Wujiaping Formation.

6.4 Causes of Carbon Isotope Inversion in Natural Gas in T₂l⁴ in the Yuanba Gas Field

The phenomenon of carbon isotope inversion in alkane gas has been reported for a long time (Stahl et al., 1975; Fuex, 1977; Burruss et al., 2010) and later studied by Tilley et al. (2011), Zumberge et al. (2012), and many others. This phenomenon is often found in major oil and gas basins in China, especially shale gas, where carbon isotopes are mostly in reverse order (Dai et al., 2016a). There are various explanations for the isotope inversion, but none is convincing. Most of the carbon isotope inversions in this study occurred in the T₂l⁴ member of the Yuanba gas field, nine of the 14 samples have carbon isotope inversions of methane and ethane, that is, δ¹³C₂<δ¹³C₁. The inverted samples were nearly 65% (Table 1; Figure 7). Some samples from the Xujiahe Formation in the Yuanba gas field have carbon isotope inversions of methane and ethane, and the samples are all distributed in the T₃x² member, such as wells YL 9 and YL 10 (Table 1). No carbon isotope inversions were found in either T₂l⁴ or Xujiahe Formation gas reservoirs in the Longgang gas field, and no carbon isotope inversions occurred in any of the other gas reservoirs.

First, we think that the carbon isotope inversion presented in this study can rule out the reason caused by mixing different natural gases. The natural gas generated from the Xujiahe Formation can migrate downward to the T₂l⁴ gas reservoir, which is common in the Longgang gas field. Half of the samples from the T₂l⁴ gas reservoir in the Longgang gas field are humic gas, while only a few samples from T₂l⁴ gas reservoir in the Yuanba gas field are humic gas (Figure 8). This indicates that the scale of humic gas of the Xujiahe Formation mixed into the T₂l⁴ gas reservoir in Longgang is larger than that in Yuanba. However, the natural gas of the Longgang T₂l⁴ member does not appear reversed, while most samples of the Yuanba T₂l⁴ member with little humic gas appear carbon isotope inversion. In addition, no sapropel gas samples were found in the Xujiahe Formation gas reservoir in the Longgang gas field, indicating that the natural gas in T₂l⁴ member did not migrate upward obviously. However, more than half of the samples from the Xujiahe Formation gas reservoir in the Yuanba gas field are sapropel gas, indicating that the natural gas from the underlying T₂l⁴ gas reservoir has massively upwardly migrated into the Xujiahe Formation gas reservoir (Figure 9). Only a few individual samples showed carbon isotope inversions in the case of large amounts of sapropel gas mixed into the Xujiahe Formation in the Yuanba gas field, and the inverted samples were all found in the T₃x² member, which is close to the T₂l⁴ member, and showed typical sapropel gas, which had already inverted before leaving the T₂l⁴ member and entering the Xujiahe Formation.

FIGURE 8

FIGURE 8. Relationship between C₁/C₁₊ and δ¹³C₂ of T₂l⁴ gas in Longgang and Yuanba gas fields.

FIGURE 9

FIGURE 9. Relationship between C₁/C₁₊ and δ¹³C₂ of T₃x gas in Longgang and Yuanba gas fields.

From the carbon isotope of sapropel gas in the T₂l⁴ member of Longgang and Yuanba gas fields, the δ¹³C₂ in T₂l⁴ member of Yuanba is 2‰ more negative than that of Longgang, while the methane carbon isotope is 2‰ less negative than that of Longgang. This indicates that the hydrocarbon source rock type in the T₂l³ member of the Yuanba gas field is of a higher quality than that of Longgang gas field. The hydrocarbon source rock maturity is higher than Longgang. Therefore, it can be concluded that the carbon isotope inversion of natural gas in the Yuanba T₂l⁴ member occurred because of its good hydrocarbon source rock type and higher maturity. Because the hydrocarbon source rock type is good and very favorable for oil generation, the ethane carbon isotope will be relatively more negative and will change less with increasing evolution, while methane carbon isotopes become less negative rapidly and become less negative than ethane as source rock maturity reaches a certain level. It is difficult for humic gas to have the carbon isotope inversion of methane and ethane. Because the δ¹³C₂ in humic gas is inherently much less negative, the carbon isotope of methane generated during the evolution of source rocks is difficult to be less negative than ethane. This also explains why the methane and ethane carbon isotopes in the Changxing and Feixianguan formation gas reservoirs did not reverse.

7 Conclusion

The natural gas of the Leikoupo Formation in the Sichuan Basin has complex genetic types and various gas sources. The natural gas in the T₂l¹ gas reservoir of the Moxi gas field is all sapropel-type, which comes from the sapropel source rock of the Upper Permian Wujiaping Formation. The natural gas in the T₂l³ gas reservoir of the Zhongba gas field is mainly sapropel gas, which comes from hydrocarbon source rocks of T₂l³ itself. Half of the natural gas in T₂l⁴ gas reservoir of the Longgang gas field is humic gas from the humic source rocks of the Xujiahe Formation, and the other half is sapropel gas from the T₂l³ source rocks. The gas in T₂l⁴ gas reservoir of the Yuanba gas field is mainly sapropel gas from the T₂l³ hydrocarbon source rocks, and a very small portion is humic gas from the Xujiahe Formation source rocks. The natural gas with inversed carbon isotopes of methane and ethane was formed from favorable quality source rocks at a higher evolution stage.

Data Availability Statement

The original contributions presented in the study are included in the article/Supplementary Material; further inquiries can be directed to the corresponding author.

Author Contributions

SQ put forward the opinion of article and wrote the manuscript. BZ compiled the diagrams. CH collected data. JL collected sample, performed analysis, and helped with manuscript translation. JW helped with sample analysis and manuscript translation. GT helped with sample analysis and manuscript translation. ZZ helped some data interpretation and manuscript revision.

Conflict of Interest

Authors SQ, BZ, and CH were employed by the company Southwest Oil and Gas Company, PetroChina.

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

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors, and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.

Acknowledgments

This study was jointly sponsored by the National Natural Science Foundation of China (Grant Nos. 41872162, 42141022). We thank Jamie Beagle for language correction. We are grateful to the editor for handling this manuscript and reviewers for helpful comments and suggestions that have improved the manuscript.

References

Bian, C., Wang, Z., Jiang, Q., Chi, Y., and Xu, Z. (2019). Characteristics and Distribution of Karst Reservoirs in the Leikoupo Formation, Western Sichuan Basin. China Pet. Explor. 24 (1), 82–94. doi:10.3969/j.issn.1672-7703.2019.01.009

CrossRef Full Text | Google Scholar

Burruss, R. C., and Laughrey, C. D. (2010). Carbon and Hydrogen Isotopic Reversals in Deep Basin Gas: Evidence for Limits to the Stability of Hydrocarbons. Org. Geochem. 41, 1285–1296. doi:10.1016/j.orggeochem.2010.09.008

CrossRef Full Text | Google Scholar

Cross, M. M., Manning, D. A. C., Bottrell, S. H., and Worden, R. H. (2004). Thermochemical Sulphate Reduction (TSR): Experimental Determination of Reaction Kinetics and Implications of the Observed Reaction Rates for Petroleum Reservoirs. Org. Geochem. 35 (4), 393–404. doi:10.1016/j.orggeochem.2004.01.005

CrossRef Full Text | Google Scholar

Dai, H., Huang, D., Liu, X., Yang, Y., He, X., Peng, H., et al. (2008). Characteristics and Evaluation of Marine Source Rock in Southwestern Shunan. Nat. Gas. Geosci. 19 (4), 503–508. doi:10.11764/j.issn.1672-1926.2008.04.503

CrossRef Full Text | Google Scholar

Dai, J. (1993). Characteristics of Carbon and Hydrogen Isotopes of Natural Gases and Their Discriminations. Nat. Gas. Geosci. 2 (3), 1–40. doi:10.11764/j.issn.1672-1926.1993.02.1

CrossRef Full Text | Google Scholar

Dai, J., Chen, J., Zhong, N., and Qin, S. (2003). The Gas Fields and Their Origins in China. Beijing: Science Press, 28–33.

Google Scholar

Dai, J., Ni, Y., Huang, S., Gong, D., Liu, D., Feng, Z., et al. (2016a). Secondary Origin of Negative Carbon Isotopic Series in Natural Gas. J. Nat. Gas Geoscience 1 (1), 1–7. doi:10.1016/j.jnggs.2016.02.002

CrossRef Full Text | Google Scholar

Dai, J., Ni, Y., Zhang, W., Huang, S., Gong, D., Liu, D., et al. (2016b). Relationships between Wetness and Maturity of Coal-Derived Gas in China. Petroleum Explor. Dev. 43 (5), 675–678. doi:10.1016/s1876-3804(16)30088-x

CrossRef Full Text | Google Scholar

Dai, J., Pei, X., and Qi, H. (1996). Natural Gas Geology in China Vol. 1. Beijing: The Petroleum Industry Press, 14–15.

Google Scholar

Dai, J. (1980). Preliminary Research on Natural Gas in Coal Series in China. Acta Pet. Sin. 1 (4), 27–37. doi:10.7623/syxb198004003

CrossRef Full Text | Google Scholar

Deng, Y., Hu, G., and Zhao, C. (2018). Geochemical Characteristics and Origin of Natural Gas in Changxing-Feixianguan Formations from Longgang Gas Field in the Sichuan Basin, China. Nat. Gas. Geosci. 29 (6), 892–907. doi:10.11764/j.issn.1672-1926.2018.03.016

CrossRef Full Text | Google Scholar

Fan, Z. (2014). Distribution of Ancient Ditches in Leikoupo Formation and its Control over Gas Accumulations in Yuanba Gas Field. Petroleum Geol. Exp. 36 (5), 562–566. doi:10.11781/sysydz201405562

CrossRef Full Text | Google Scholar

Fuex, A. N. (1977). The Use of Stable Carbon Isotopes in Hydrocarbon Exploration. J. Geochem. Explor. 7, 155–188. doi:10.1016/0375-6742(77)90080-2

CrossRef Full Text | Google Scholar

Guo, X., and Guo, T. (2012). Theory and Practice of Exploration of Large Gas Fields at the Margin of the Puguang and Yuanba Carbonate Platforms. Beijing: Science Press, 413.

Google Scholar

Hao, F., Guo, T., Zhu, Y., Cai, X., Zou, H., and Li, P. (2008). Evidence for Multiple Stages of Oil Cracking and Thermochemical Sulfate Reduction in the Puguang Gas Field, Sichuan Basin, China. Bulletin 92 (5), 611–637. doi:10.1306/01210807090

CrossRef Full Text | Google Scholar

Hu, G., Yu, C., Gong, D., Tian, X., and Wu, W. (2014a). The Origin of Natural Gas and Influence on Hydrogen Isotope of Methane by TSR in the Upper Permian Changxing and the Lower Triassic Feixianguan Formations in Northern Sichuan Basin, SW China. Energy Explor. Exploitation 32 (1), 139–158. doi:10.1260/0144-5987.32.1.139

CrossRef Full Text | Google Scholar

Hu, W., Zhu, Y., Li, Y., Zou, H., and Guo, T. (2014b). Geochemical Characteristics and Origin of Natural Gases from Terrestrial Strata in Yuanba Area of the Northeastern Sichuan Basin. J. Zhejiang Univ. Sci. Ed. 41 (4), 468–476. doi:10.3785/j.issn.1008-9497.2014.04.020

CrossRef Full Text | Google Scholar

Huang, R. (2014). Source and Accumulation of Natural Gas in Leikoupo Formation, Yuanba Area, Eastern-Northern Sichuan Basin. Geoscience 28 (2), 412–418. doi:10.3969/j.issn.1000-8527.2014.02.020

CrossRef Full Text | Google Scholar

Hussain, M., and Warren, J. K. (1991). Source Rock Potential of Shallow-Water Evaporites: An Investigation in Holocenepleistocene Salt Flat Sabkah (Playa), West Texas-New Mexico. Carbonates Evaporites 6 (2), 217–224. doi:10.1007/BF03174424

CrossRef Full Text | Google Scholar

Jin, Q., and Zhu, G. (2006). Progress in Research of Deposition of Oil Source Rocks in Saline Lake and Their Hydrocarbon Generation. Geol. J. China Univ. 12 (4), 483. doi:10.3969/j.issn.1006-7493.2006.04.009

CrossRef Full Text | Google Scholar

Krouse, H. R., Viau, C. A., Eliuk, L. S., Ueda, A., and Halas, S. (1988). Chemical and Isotopic Evidence of Thermochemical Sulphate Reduction by Light Hydrocarbon Gases in Deep Carbonate Reservoirs. Nature 333, 415–419. doi:10.1038/333415a0

CrossRef Full Text | Google Scholar

Krzywiec, P., Peryt, T. M., Kiersnowski, H., Pomianowski, P., Czapowski, G., and Kwolek, K. (2017). Permo-Triassic Evaporites of the Polish Basin and Their Bearing on the Tectonic Evolution and Hydrocarbon System, an Overview. Permo-Triassic salt Prov. Eur. North Afr. Atl. Margins 2017, 243–261. doi:10.1016/B978-0-12-809417-4.00012-4

CrossRef Full Text | Google Scholar

Li, W. (2011). Formation of a Saline Enviroment and Evolution of a Sedimentary System in the Late Triassic of the Sichuan Basin. Nat. Gas. Ind. 31 (9), 31–38. doi:10.3787/j.issn.1000-0976.2011.09.006

CrossRef Full Text | Google Scholar

Li, W., Zou, C., Yang, J., Wang, K., Yang, J., Wu, Y., et al. (2010). Types and Controlling Factors of Accumulation and High Productivity in the Upper Triassic Xujiahe Formation Gas Reservoirs, Sichuan Basin. Acta Sedimentol. Sin. 28 (5), 1037–1045. doi:10.14027/j.cnki.cjxb.2010.05.018

CrossRef Full Text | Google Scholar

Li, Z. (1993). Surveying Gas Prospects of Leikoupo Formation in West Sichuan. Nat. Gas. Ind. 13 (2), 28–33. doi:10.11821/yj1983040003

CrossRef Full Text | Google Scholar

Liao, F., Wu, X., Huang, S., and Yu, C. (2013). Geochemical Characeristics and Gas Source Correlation of Leikoupo Formation in Zhongba Field, Northwest Sichuan Basin. Nat. Gas. Geosci. 24 (1), 108–115. doi:10.11764/j.issn.1672-1926.2013.01.108

CrossRef Full Text | Google Scholar

Liu, J., Liu, G., Wang, L., and Wu, X. (2014). Geochemical Characteritics and Origin of Permain and Triassic Natural Gas in Yuanba-Tongnanba Area, Northeastern Sichuan Basin. Acta Pet. Sin. 35 (3), 417–428. doi:10.7623/syxb201403002

CrossRef Full Text | Google Scholar

Liu, R., Guo, T., and Shao, M. (2011). Source and Genetic Types of Gas in the Middle-Shallow Strata of the Yuanba Area, Northeast Sichuan Basin. Nat. Gas. Ind. 31 (6), 34–38. doi:10.3787/j.issn.1000-0976.2011.06.005

CrossRef Full Text | Google Scholar

Liu, S., Sun, W., Song, J., Yong, Z., Wang, H., and Zhao, C. (2019). The Key Geological Promblems of Natural Gas Exploration in the Middle Triassic Formation in Sichuan Basin. Nat. Gas. Geosci. 30 (2), 151–167. doi:10.11764/j.issn.1672-1926.2018.12.011

CrossRef Full Text | Google Scholar

Luo, Q. (1983). Discovery of Water-Transgression Cause Filling Sand-Bodies in Ancient Sediments-An Approach to the Genesis of Certain Upper Triassic Sand-Bodies in the Middle-Western Part of the Sichuan Basin and Discussion on Water-Transgression Delta. Acta Sedimentol. Sin. 1 (3), 59–67. CNKI:SUN:CJXB.0.1983-03-004.

Google Scholar

Luo, Q. (2011). Understanding of the Upper Triassic Sedimentary Facies in the Sichuan Basin. Nat. Gas. Ind. 31 (9), 12–15. doi:10.3787/j.issn.1000-0976.2011.09.003

CrossRef Full Text | Google Scholar

Machel, H. G. (2001). Bacterial and Thermochemical Sulfate Reduction in Diagenetic Settings-Old and New Insights. Sediment. Geol. 140 (1-2), l43–175. doi:10.1016/S0037-0738(00)00176-7

CrossRef Full Text | Google Scholar

Peng, C., Liu, K., Zhang, Y., and Zhu, P. (2011). Seismic Sedim Entology of Organic Reef from the Changxing Form Ation of Central Sichuan. Nat. Gas. Geosci. 22 (3), 460–464. doi:10.11764/j.issn.1672-1926.2011.03.460

CrossRef Full Text | Google Scholar

Qin, H., Pan, L., Yin, F., and Shen, J. (2016b). Discution on Source of Natural Gas and Causation of Reversed Orders of δ13C in Alkane Gas from Leikoupo Formation in Yuanba, Sichuan Basin, China. J. Chengdu Univ. Technol. Sci. Technol. Ed. 43 (5), 591–600. doi:10.3969/j.issn.1671-9727.2016.05.09

CrossRef Full Text | Google Scholar

Qin, S., Tao, S., Tu, T., Wei, X., and Song, M. (2007). Characeristics of Natural Gas Geochemistry and Accumulation in Western Sichuan Depression. Petroleum Explor. Dev. 34 (1), 34–38. doi:10.3321/j.issn:1000-0747.2007.01.007

CrossRef Full Text | Google Scholar

Qin, S., Yang, Y., Lü, F., Zhou, H., and Li, Y. (2016a). The Gas Origin in Changxing-Feixianguan Gas Pools of Longgang Gasfield in Sichuan Basin. Nat. Gas. Geosci. 27 (1), 40–48. doi:10.11764/j.issn.1672-1926.2016.01.0041

CrossRef Full Text | Google Scholar

Song, W., Liu, L., Gan, X., Qin, Q., Su, P., and Fan, C. (2012). Weathering Crust Karstification in Leikoupo Formation in Central Sichuan Area. Nat. Gas. Geosci. 23 (6), 1019–1024. CNKI:SUN:TDKX.0.2012-06-007.

Google Scholar

Stahl, W. J., and Carey, B. D. (1975). Source-rock Identification by Isotope Analyses of Natural Gases from Fields in the Val Verde and Delaware Basins, West Texas. Chem. Geol. 16, 257–267. doi:10.1016/0009-2541(75)90065-0

CrossRef Full Text | Google Scholar

Sun, H., Luo, B., Wen, L., Wang, J., Zhou, G., Wen, H., et al. (2021). The First Discovery of Organic-Rich Shale in Leikoupo Formation and New Areas of Subsalt Exploration, Sichuan Basin. Nat. Gas. Geosci. 32 (2), 233–247. doi:10.11764/j.issn.1672-1926.2020.11.011

CrossRef Full Text | Google Scholar

Tilley, B., McLellan, S., Hiebert, S., Quartero, B., Veilleux, B., and Muehlenbachs, K. (2011). Gas Isotope Reversals in Fractured Gas Reservoirs of the Western Canadian Foothills: Mature Shale Gases in Disguise. Bulletin 95 (8), 1399–1422. doi:10.1306/01031110103

CrossRef Full Text | Google Scholar

Wang, S., Dai, H., Wang, T., and Lin, F. (1998). Gas Source and Migration of High-Mature Natural Gas in Moxi Gas Field. Petroeum Explor. 3 (2), 5–8. CNKI:SUN:KTSY.0.1998-02-002.

Google Scholar

Wang, S., Luo, Q., and Wu, D. (1997). Organic Petrology of Source Rocks from the Upper Triassic Coal Measures in the Central and Western Sichuan Basin. J. Mineral Pet. 17 (1), 63–70.

Google Scholar

Wang, T., Zhen, Y., Li, S., Zeng, Q., and He, J. (1989). From Geochemical Characteristics of Oil and Gas to Discuss the Gas Source of Lei-3 Reservoir, Zhongba Gas Field, in Northwest Sichuan. Nat. Gas. Ind. 9 (5), 20–26. CNKI:SUN:TRQG.0.1989-05-004.

Google Scholar

Wang, W., Xu, G., Dan, Y., Song, X., Wang, Q., Feng, X., et al. (2018a). Unconformity Characeristics of the Top of Leikoupo Formation and Their Effect on Reservoirs in the Western Sichuan Basin. Carsologica Sin. 37 (4), 592–601. doi:10.11932/karst20180413

CrossRef Full Text | Google Scholar

Wang, Y., Chen, Y., Hu, Y., Zeng, H., and Wu, X. (2018b). Discussion on Hydrocarbon Generation Ability of Evaporation Environment: A Case Study of Leikoupo Formation in West Sichuan Depression. Fault-Block oil Gas Fied 25 (4), 426–430. doi:10.6056/dkyqt201804004

CrossRef Full Text | Google Scholar

Wen, L., Zhang, Q., Yang, Y., Liu, H., Che, Q., Liu, W., et al. (2012). Factors Controlling Reef-Bank Reservoirs in the Changxing-Feixianguan Formations in the Sichuan Basin and Their Play Fairways. Nat. Gas. Ind. 32 (1), 39–44. doi:10.3787/j.issn.1000-0976.2012.01.007

CrossRef Full Text | Google Scholar

Whiticar, M. J. (1999). Carbon and Hydrogen Isotope Systematics of Bacterial Formation and Oxidation of Methane. Chem. Geol. 161 (1/2/3), 291–314. doi:10.1016/S0009-2541(99)00092-3

CrossRef Full Text | Google Scholar

Worden, R. H., Smalley, P. C., and Oxtoby, N. H. (1995). Gas Souring by Thermochemical Sulfate Reduction at 140øC. Bulletin 79, 854–863. doi:10.1306/8d2b1bce-171e-11d7-8645000102c1865d

CrossRef Full Text | Google Scholar

Wu, X., Liu, G., Liu, Q., Liu, J., and Yuan, X. (2015). Geochemical Characteristics and Genetic Types of Natural Gas in the Changxing-Feixianguan Formations from Yuanba Gasfield in the Sichuan Basin. Nat. Gas. Geosci. 26 (11), 460–464. doi:10.11764/j.issn.1672-1926.2015.11.2155

CrossRef Full Text | Google Scholar

Xie, F., Wu, Q., Wang, L., Shi, Z., Zhang, C., Liu, B., et al. (2019). Passive Continental Margin Basins and the Controls on the Formation of Evaporites: A Case Study of the Gulf of Mexico Basin. Carbonates Evaporites 34 (2), 405–418. doi:10.1007/s13146-017-0404-z

CrossRef Full Text | Google Scholar

Xu, G., Song, X., Feng, X., Long, K., Wang, Q., Shi, G., et al. (2013). Gas Potential of the Middle Triassic Leikoupo Fm in the Western Sichuan Basin. Nat. Gas. Ind. 33 (8), 8–14. doi:10.3787/j.issn.1000-0976.2013.08.002

CrossRef Full Text | Google Scholar

Yang, G., Shi, X., Huang, D., Wang, H., and Ding, W. (2014). Characteristics and Major Controls of Weathering Crust Reservors in T2l43 in the Longgang Gas Field, Sichuan Basin. Nat. Gas. Ind. 34 (9), 17–24. doi:10.3787/j.issn.1000-0976.2014.09.003

CrossRef Full Text | Google Scholar

Yang, K. (2016). Hydrocarbon Potential of Source Rocks in the Middle Triassic Leikoupo Formation in the Western Sichuan Depression. Petroleum Geol. Exp. 38 (3), 366–374. doi:10.11781/sysydz201603366

CrossRef Full Text | Google Scholar

Yang, X., Zou, C., Tao, S., Wang, Z., Li, J., and Wang, S. (2005). Characteristics of Upper Triassic-Jurassic Oil and Gas System in Sichuan Basin and Oli and Gas Abundance Law. China Pet. Explor. 10 (2), 15–22. doi:10.3969/j.issn.1672-7703.2005.02.003

CrossRef Full Text | Google Scholar

Yin, F., Liu, R., Wang, W., Zhang, Y., and Pan, L. (2013). Geochemical Characters of the Tight Sandstone Gas from Xujiahe Formation in Yuanba Gas Field and its Gas Source. Nat. Gas. Geosci. 24 (3), 621–627. doi:10.11764/j.issn.1672-1926.2013.03.621

CrossRef Full Text | Google Scholar

Yu, K., Cao, Y., Qiu, L., and Sun, P. (2018). The Hydrocarbon Generation Potential and Migration in an Alkaline Evaporite Basin: The Early Permian Fengcheng Formation in the Junggar Basin, Northwestern China. Mar. Petroleum Geol. 98, 12–32. doi:10.1016/j.marpetgeo.2018.08.010

CrossRef Full Text | Google Scholar

Zeng, D., Wang, X., Zhang, F., Song, Z., Zhang, R., Zhu, Y., et al. (2007). Study on Reservoir of the Leikoupo Formation of Middle Triassic in Northwestern Sichuan Basin. J. Palaeogeogr. 9 (3), 253–266. doi:10.3969/j.issn.1671-1505.2007.03.003

CrossRef Full Text | Google Scholar

Zhang, J., Zhou, J., Pan, L., Wang, X., Wang, F., Hao, Y., et al. (2013). The Main Origins of High Quality Reservoir in Feixianguan Formation in Northeast Sichuan Basin: Atmospheric Water Eluviation and Seepage-Reflux Dolomitization. Nat. Gas. Geosci. 24 (1), 9–18.

Google Scholar

Zheng, Y., Lin, F., Wang, T., and Yan, W. (1990). Geologic and Geochemical Conditions of Formation of Zhongba Condensate Gas Fields in Northwest Sichuan. J. Southwest Petroleum Inst. 12 (4), 18–30. doi:10.3863/j.issn.1000-2634.1990.04.003

CrossRef Full Text | Google Scholar

Zhou, S., Wang, X., Zeng, D., He, B., and Zhou, X. (2015). Geochemistry and Accumulation Analysis of Gas Reservoir of Leikoupo 43 Sub-member of Middle Triassic in Longgang Area, Central Sichuan Basin. Xinjiang Pet. Geol. 36 (4), 415–422. doi:10.7657/XJPG20150407

CrossRef Full Text | Google Scholar

Zhu, H., and Zhong, D. (2013). Characteristics and Formation Mechanism of the Triassic Feixianguan Formation Reservoir in Longgang Gas Field, Sichuan Basin. J. Palaeogeogr. 15 (2), 275–282. doi:10.7605/gdxh.2013.02.023

CrossRef Full Text | Google Scholar

Zumberge, J., Ferworn, K., and Brown, S. (2012). Isotopic Reversal (‘rollover') in Shale Gases Produced from the Mississippian Barnett and Fayetteville Formations. Mar. Petroleum Geol. 31, 43–52. doi:10.1016/j.marpetgeo.2011.06.009

CrossRef Full Text | Google Scholar