- 1School of Geoscience and Technology, Southwest Petroleum University, Chengdu, China
- 2Sichuan Natural Gas Geology Key Laboratory Southwest Petroleum University, Chengdu, China
- 3State Key Laboratory of Oil and Gas Reservoir Geology and Exploitation, Southwest Petroleum University, Chengdu, China
- 4Exploration and Development Research Institute, SINOPEC Jianghan Oil Field Company, Wuhan, China
- 5Zhejiang Oilfield Company, PetroChina, Hangzhou, China
- 6Research Institute of Shale Gas, Southwest Oil and Gas Field Company, PetroChina, Chengdu, China
Pyrite is widely distributed in the Longmaxi marine shale in the Upper Yangtze area of China. Pyrite, one of the important components of shale, has an important influence on the enrichment of shale gas. However, there are currently only a few studies on this topic. Based on shale samples from drilling cores using field emission scanning electron microscopy, the pore characteristics of pyrite from the Longmaxi Formation in the Upper Yangtze area of China are studied. The results showed that the intergranular pores of pyrite and abundant organic pores in the organic matter pyrite assemblages are developed in the Longmaxi Formation shale in the study area. Most pyrite framboid pores have triangular or irregular quadrilateral shapes, with pore diameters ranging from 0 to 240 nm. Pores with diameters of 80–240 nm are the major reservoir spaces for shale gas within the pyrite framboids. The average contribution rate of pyrite framboids to shale pores reaches 3.21%, and the highest contribution is 5.66%, indicating that the pyrite pores may have a favorable contribution to the shale reservoir pore system, but the contribution degree is low.
Introduction
In recent years, the exploration and development of shale gas have achieved a great success in North America and the Sichuan Basin in China (Hao et al., 2013; Chen et al., 2015; Zou et al., 2016; Chen et al., 2019; Shu et al., 2020), which has attracted worldwide attention. Nanopores in shale reservoirs are well developed in diverse types and structures, effectively providing storage space for shale gas. The structural characteristics of nanopores are important and difficult aspects of the theoretical study of shale gas geology (Ross and Bustin, 2008a; Clarkson et al., 2013). Pore characteristics are important determinants of the gas content in shale gas reservoirs and are the keys to shale reservoir evaluation. Therefore, studying the pore characteristics of reservoirs is of great significance for shale gas exploration, development, and resource potential evaluation (Loucks et al., 2009; Roger and Neal, 2011; Gao et al., 2019).
Scholars have performed many studies on the pore characteristics and structure of marine shale, including different types of pores, pore structures, and connectivity of shale gas reservoirs on different scales (Loucks et al., 2009; Kuila and Prasad, 2013; Zargari et al., 2015; Jiang et al., 2016; Zheng et al., 2019). Presently, the research contents on shale pore structure mainly focused on 1) shale pore classification (IUPAC, 1994; Slatt and O’Brien, 2011; Ruppel et al., 2012; Yu, 2013), 2) microstructural characteristics of shale pores (Loucks et al., 2009; Ross and Bustin, 2008b; Jiang et al., 2016), 3) formation mechanisms of shale pores and factors influencing pore development (Jarvie et al., 2007; Chalmers and Bustin, 2008; Zhang et al., 2016; Zheng et al., 2019), and 4) shale pore evolution (Chen and Xiao, 2014; Lu et al., 2015; Zargari et al., 2015; Tang et al., 2015). The results have shown that the organic matter type, maturity, and mineral composition are closely related to the pore structure (Kuila and Prasad, 2013; Duan et al., 2016; Wei et al., 2016). With increasing thermal evolution level, organic matter transforms to hydrocarbons, and nanopores are widely developed in organic-rich shale, thereby providing abundant storage space for shale gas. The major types of pores and fractures in shale reservoirs are organic pores, intragranular pores, intergranular pores, and microfractures. Nanopores mainly provide connected storage space for shale gas (Ruppel et al., 2012; Yu, 2013).
Current research studies on pyrite in shale mainly focuses on the following aspects: 1) the correlation between pyrite and the shale sedimentary environment (Wilkin et al., 1996; Raiswell et al., 1988; Butler and Rickard, 2000; Liu et al., 2019), and 2) the organic matter content is proportional to the pyrite content (Xu et al., 2015; Liu et al., 2016). Many scholars have found that pores related to pyrite in marine shale are universally developed (Bernard et al., 2012; Wang Q. et al., 2014; Cao et al., 2018; Zhao et al., 2018; Tang et al., 2019). Although shale pores are fully studied, there are few reports on pores related to pyrite in shale. To determine the development characteristics of pyrite pores, especially pores within the pyrite framboids and their geological significance, pyrite pores in the marine shale of the Longmaxi Formation in the Upper Yangtze area were studied in this research.
Geological Setting
Organic-rich shale (TOC>2%) is well developed in the Wufeng Formation and the first member of the Longmaxi Formation in the Upper Yangtze area, and kerogen is mainly composed of sapropel (Types I-II1). The organic-rich shale is widely distributed in the Upper Yangtze area, with burial depths ranging from 1,500 m to 4,500 m. The Longmaxi marine shale is characterized by large thicknesses (20–50 m), high TOC, and high maturity, and is one of the most favorable shale gas exploration targets in China (Zou et al., 2014; Guo, 2015; Tenger et al., 2017; Shan et al., 2017).
Previous studies have shown that the high-quality shale section of the Longmaxi Formation is mainly in S1l1, which can be divided into two sub sections. S1l11 is the most favorable interval for the exploration and development of high-quality shale in the Longmaxi Formation (Zou et al., 2016). S1l11 can be divided into 4 sub-layers (Zhao et al., 2016). The study area is mainly in the Upper Yangtze region. Taking well X2 as an example, S1l11 mainly contains gray–black and black silty shale with a thickness of approximately 36 m (Figure 1).
FIGURE 1. Location of the study area and stratigraphic column of the Longmaxi Formation and the gamma-ray log of the X2 well (Wang et al., 2002).
S1l11−1 contains black silty shale with a thickness of approximately 1.2 m, the TOC contents are within 3–6%, and the pyrite contents are within 2–8%. S1l11−2 comprises gray–black silty shale and carbonaceous shale with a thickness of approximately 9.5 m. The TOC contents are within 3–4%, and the pyrite contents are within 2–6%. S1l11−3 contains gray–black carbonaceous shale and silty shale, is approximately 8.5 m thick, and has TOC contents within 2–4% and pyrite contents within 2–8%. S1l11−4 comprises gray–black shale and silty shale, has a thickness of approximately 23.2 m, and low TOC contents of 1.5–2.5% and pyrite contents of 1–4% (Figure 1).
Materials and Methods
To characterize the pores related to pyrite in the Longmaxi Formation shale in the Upper Yangtze area, eight shale samples from drilling cores of well X2 drill cores were used in this study for argon ion polishing field emission scanning electron microscopy (FE-SEM) analysis and quantitative characterization experiments of pores in pyrite (Table 1).
FE-SEM
Core samples were cut into standard samples of 1 cm × 1 cm. Then, an IB-09010CP ion section polishing instrument was used for argon ion polishing processing on the surfaces of the samples. A JSM-6700F cold field emission scanning electron microscope was used for image collection at a 10 KV acceleration voltage and 10 μA beam current.
Pyrite Content
First, the shale rock sample was dried and crushed into a powder with a grain size less than 40 μm, and finally made into a test piece for later use. Each type of mineral crystal has a specific X-ray diffraction spectrum through which qualitative and quantitative results can be obtained because the characteristic peak strength in the spectrum is related to the mineral content of the sample. The XRD test was accomplished by using the Panalytical X'Pert PRO MPD X-ray diffractometer.
Quantitative Characterization of Pyrite Pores
To quantitatively study the contribution of pores within the pyrite framboids to the total porosity of the shale reservoir, the following technical methods were applied: 1) FE-SEM (scanning electron microscope) was used to obtain microscopic images of shale, and the shale images were magnified to the μm–nm scale to observe the pyrite framboids; 2) image analysis software was used for image gray level segmentation to calculate the area of pyrite and shale pores; 3) pyrite framboids were demarcated, multiple individual pyrite framboids were selected to calculate the development area of pyrite framboids, and the pore area and aperture of developed pores in the microscopic area were ascertained to calculate the average face rate of pore development in pyrite framboids; and 4) the approximate contributions of pyrite framboids to the total porosity of shale were quantitatively represented by multiplying the area percentage of pyrite area in the microscopic image by the average face rate of pyrite framboids and by dividing by the total face rate of shale in the microscopic image (Figure 2).
Results and Discussion
Pore Types in Pyrite in Shale
The common pore types in pyrite in the Longmaxi Formation shale in the Upper Yangtze area are as follows: abundant organic pores are developed in the organic matter pyrite assemblages; these pores are the most common type of pores that are closely related to pyrite in the Longmaxi Formation shale (Figure 3). A small number of irregular intercrystalline pores are found within the pyrite framboids, appearing as monomers, composed of pyrite microcrystalline groups but not filled by organic matter (Figure 3D). Intergranular and organic pores in pyrite can provide space for the preservation of shale gas.
FIGURE 3. Common pore types associated with pyrite in the Longmaxi Formation shale in the southeastern basin. (A) Organic pore in pyrite framboid, X2 well, 2376.05 m; (B) organic pore in pyrite framboid, X2 well, 2385.42 m; (C) organic pore in pyrite framboid, X2 well, 2385.42 m; (D) intergranular pore of pyrite, X2 well, 2335.30 m.
According to FE-SEM analysis, the organic pores related to pyrite (Figure 3, B1, C1) are much more numerous and larger than individual organic pores that are developed far away from the pyrite (Figure 3, B2, C2), which means that pyrite may influence hydrocarbon generation and expulsion of organic matter and pore development. Organic pores in the organic matter pyrite assemblages mainly occur for the following two reasons: 1) The organic pores in pyrite as shown in Figure 3A are supported and protected by the stable triangular stress lattice generated between pyrite microcrystalline grains from later diagenesis (compaction) (Sun and Guo, 2017; Zhao et al., 2018). 2) Pyrite can catalyze the hydrocarbon generation of organic matter, which promotes the development of more organic pores in organic matter around pyrite (Hunt et al., 1991; Mango, 1992; Cui et al., 2013; Wang Y. M. et al., 2014; Cai et al., 2016; Ma et al., 2017).
Characteristics of Nanopores in Pyrite
Pyrite occurs mainly in the form of pyrite framboids in shale. Nanopores (intergranular pores and organic pores in pyrite framboids) are one of the basic reservoir pore types in shale (Loucks et al., 2009; Yu, 2013; Curtis et al., 2012; Guo et al., 2014) and play an important role in the shale reservoir pore system (Hu et al., 2015; Cao et al., 2018).
According to the FE-SEM analysis of the shale samples from well X2, the pore characteristics of pyrite framboids in shale are studied. According to the research, the organic pores of pyrite framboids in sample 1 are well developed and have a face rate reaching 7.01%. The pore diameter is relatively dispersive and is mainly divided into two categories: pores with a diameter of <80 nm account for 72.12%, with an area frequency of 5.41%, and pores with a diameter of 80–240 nm account for 22.96%, with an area frequency of 47.68%. In sample 2, the pore diameters of pyrite framboids are relatively dispersed and are within 0–280 nm, with a face rate of 3.35%; these pore diameters are mainly divided into two categories: pores with a diameter of <80 nm account for 61.94%, with an area frequency of 22.19%, and pores with a diameter of 80–240 nm account for 37.17%, with an area frequency of 71.64%. In sample 3, pyrite framboids are well crystallized in an ellipsoidal shape, with the face rate reaching 1.47%. The pore diameters of pyrite framboids are relatively small overall and are <80 nm, with an area frequency of 58.44%. In sample 5, pyrite framboids show relatively inferior crystallization, with a face rate of 4.10%. The pore diameters are concentrated within <80 nm and from 80 to 240 nm overall, with pore diameter frequencies of 51.97 and 45.1% and area frequencies of 13.95 and 76.96%. In sample 7, organic pores are well developed within the dispersive microcrystalline pyrite with a face rate reaching 4.70%. The pores are mainly divided into two categories: pores with a diameter of <80 nm account for 72.84%, with an area frequency of 14.89% and pores with a diameter of 40–100 nm account for 22.22%, with an area frequency of 44.06% (Table 2; Figure 4).
FIGURE 4. Quantitative characterization of pores in pyrite framboids of shale samples from X2 well. 1, Black shale, X2 well, 2330.46 m; 2, black shale, X2 well, 2335.30 m; 3, black shale, X2 well, 2346.50 m; 5, black shale, X2 well, 2366.74 m; 7, black shale, X2 well, 2402.55 m.
Overall, pores in pyrite framboids mostly occur in triangular and trapezoidal shapes, with diameters universally smaller than 320 nm. The diameters of pores in pyrite framboids are 0–240 nm, mostly within 0–120 nm. More than 95% of the pores are smaller than 240 nm. Although most pores in pyrite framboids are in the range of 0–80 nm, their pore area ratios are relatively low, generally lower than 15%. Their contributions to pyrite pores are also low. The pores in pyrite framboids with diameters of 80–240 nm, which account for 40–75% of the pore area, are the primary storage spaces for shale gas in the pyrite framboids. Pores larger than 240 nm are less than 5%. In general, the larger the pore is, the larger the face rate will be and the better the storage property of pyrite will be.
Contributions of Nanopores in Pyrite to Shale Reservoir Pores
Taking multiple photographs (greater than or equal to 200 for every sample) of 8 shale samples in different visual fields by using FE-SEM and then calculating observation statistics on the pores in the pyrite framboids, the results showed that intracrystalline and organic pores are developed in pyrite framboid aggregates, with organic pores prevailing. For pyrite framboid aggregates (containing pyrite microcrystals) in shale, the area ratio values are 0.95–2.34%, with an average of 1.59%, and the face rate values are 1.47–6.43%, with an average of 4.26%. In addition, the face rate values of all pores in shale are 1.34–2.86%, with an average of 2.13%. The contribution of pores in pyrite to the pores in shale is 1.09–5.66%, with an average of 3.21%. These pores can not only increase the shale reservoir space and specific surface area of shale but also reserve free gas and promote the enrichment of shale gas in the Longmaxi Formation. It is shown that the pores in pyrite in shale have favorable contributions to the shale reservoir pore system (Table 3).
TABLE 3. Quantitative statistical results of pores in pyrite framboids of shale samples from X2 well.
Conclusion
The intergranular pores in pyrite and abundant organic pores in the organic matter pyrite assemblages are well developed in the Longmaxi Formation shale in the Upper Yangtze area of China. Pyrite framboids are the major forms of pyrite in shale, and most pyrite framboids pores occur in triangular or irregular quadrilateral shapes, with pore diameters mainly between 0 and 240 nm. Pores with diameters of 80–240 nm are the major reservoir spaces for shale gas in the pyrite framboids. For pyrite framboid aggregates (containing pyrite microcrystals) in shale, the face rate values are 1.47–6.43%, with an average of 4.26%, and its contributions to the pores in shale are 1.09–5.66%, with an average of 3.21%, which indicates that pyrite pores in shale may be favorable to the shale reservoir pore system. These pores can not only increase the shale reservoir space and specific surface area of shale but also reserve free gas and promote the enrichment of shale gas in the Longmaxi Formation.
Data Availability Statement
The raw data supporting the conclusions of this article will be made available by the authors, without undue reservation.
Author Contributions
XC was the major author of the article. MX and LC conceived the project. XT collected the samples. GW analyzed the samples. All authors contributed to the article and approved the submitted version.
Funding
This study was jointly funded by the National Natural Science Foundation of China (Grant No. 41602147) and Science and Technology Cooperation Project of the CNPC-SWPU Innovation Alliance (Grant No. 2020CX020000).
Conflict of Interest
WC was employed by Sinopec. YJ and GW were employed by 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.
The reviewer YS declared a shared affiliation with one of the authors, CW, to the handling editor at time of review.
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
We are grateful to the Guest Associate Editor Kun Zhang and three reviewers for their insightful and constructive comments both in science and English, which have substantially improved the article.
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Keywords: pore, pyrite, shale, Longmaxi formation, Upper Yangtze area
Citation: Chen X, Chen L, Tan X, Wang C, Ji Y, Xiong M and Wang G (2022) Pore Characterization of Pyrite in the Longmaxi Formation Shale in the Upper Yangtze Area of China. Front. Earth Sci. 10:848247. doi: 10.3389/feart.2022.848247
Received: 04 January 2022; Accepted: 11 February 2022;
Published: 01 March 2022.
Edited by:
Shu Jiang, The University of Utah, United StatesReviewed by:
Tao Hu, China University of Petroleum, ChinaXianglu Tang, China University of Petroleum, China
Yi Shu, Jianghan Oilfield Branch Company, China
Copyright © 2022 Chen, Chen, Tan, Wang, Ji, Xiong and Wang. 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: Lei Chen, Y2wyMTFAMTI2LmNvbQ==