Next Article in Journal
Sealing Characteristics Analysis of New Subsea Wellhead Sealing Device
Next Article in Special Issue
Geophysical Monitoring Technologies for the Entire Life Cycle of CO2 Geological Sequestration
Previous Article in Journal
Robustness and Scalability of Incomplete Virtual Pheromone Maps for Stigmergic Collective Exploration
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Processes
Volume 12
Issue 10
10.3390/pr12102123
processes-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Oolitic Sedimentary Characteristics of the Upper Paleozoic Bauxite Series in the Eastern Ordos Basin and Its Significance for Oil and Gas Reservoirs

by
Fengyu Sun
1,2,
Changling Qu
1,
Gaoshe Cao
1,2,*,
Liqin Xie
3,4,
Xiaohu Shi
3,4,
Shengtao Luo
5,
Zhuang Liu
5,
Ling Zhang
1,
Xiaochen Ma
1,
Xinhang Zhou
1,
Sen Zhu
1 and
Zhenzhi Wang
1
1
School of Resources and Environment, Henan Polytechnic University, Jiaozuo 454003, China
2
Collaborative Innovation Center of Coal Work Safety and Clean High Efficiency Utilization, Jiaozuo 454003, China
3
Exploration and Development Research Institute of Changqing Oilfield Company, Xi’an 710018, China
4
National Engineering Laboratory for Exploration and Development of Low Permeability Oil & Gas Fields, Xi’an 710018, China
5
Luanchuan Hengyu Mining Co., Ltd., Luoyang 471514, China
*
Author to whom correspondence should be addressed.
Processes 2024, 12(10), 2123; https://doi.org/10.3390/pr12102123
Submission received: 27 August 2024 / Revised: 19 September 2024 / Accepted: 26 September 2024 / Published: 29 September 2024
(This article belongs to the Special Issue Exploration, Exploitation and Utilization of Coal and Gas Resources, 2nd Edition)
Browse Figures
Versions Notes

Abstract

:
In recent years, great breakthroughs have been made in gas explorations of the Upper Paleozoic bauxite series in the Longdong area of the Ordos Basin, challenging the understanding that bauxite is not an effective reservoir. Moreover, studying the reservoir characteristics of bauxite is crucial for oil and gas exploration. Taking the bauxite series in the Longdong area as an example, this study systematically collects data from previous publications and analyzes the petrology, mineralogy, oolitic micro-morphology, chemical composition, and other sedimentary characteristics of the bauxite series in the study area using field outcrops, core observations, rock slices, cast slices, X-ray diffraction analysis, scanning electron microscopy and energy spectra, and so on. In this study, the oolitic microscopic characteristics of the bauxite reservoir and the significance of oil and gas reservoirs are described. The results show that the main minerals in the bauxite reservoir are boehmite and clay minerals composed of 73.5–96.5% boehmite, with an average of 90.82%. The rocks are mainly bauxitic mudstone and bauxite. A large number of oolites are observable in the bauxite series, and corrosion pores and intercrystalline pores about 8–20 μm in size have generally developed. These pores are important storage spaces in the reservoir. The brittleness index of the bauxite series was found to be as high as 99.3%, which is conducive to subsequent mining and fracturing. The main gas source rocks of oolitic bauxite rock and the Paleozoic gas series are the coal measure source rocks of the Upper Paleozoic. The oolitic bauxite reservoirs in the study area generally have obvious gas content, but the continuity of the planar distribution of the bauxite reservoirs is poor, providing a scientific basis for studying bauxite reservoirs and improving the exploratory effects of bauxite gas reservoirs.

1. Introduction

The Changqing oilfield has obtained a high-yield gas flow with an open flow rate of 673,800 m3/d in the bauxite reservoir of well L47 in the Longdong area, representing the first breakthrough in this area. The bauxite gas reservoir in the Ordos Basin also shows good exploratory potential. [1,2,3,4,5]. This achievement challenges the understanding that bauxite is not an effective reservoir and opens up a new field of study, as it is imperative to analyze the characteristics of reservoirs. In recent years, scholars have paid increasing attention to the analysis of bauxite reservoirs. The mineralogical characteristics and formation mechanisms of bauxite series have been clarified through core tests and analyses, with the composition mainly featuring aluminous and clay minerals of sedimentary origin [2,6]. The reservoir formation process has been analyzed based on the controlling factors of bauxite gas reservoirs and the lithological traps under structural action [7,8,9,10]. The lithology, physical properties, gas-bearing properties, and pore structures of bauxite reservoirs have been analyzed using logging data [5,11,12]. In addition, basic geological problems such as the reservoir characteristics, provenance, and distribution law of bauxite series represent additional research hotspots. Analysis shows that the porosity of bauxite series is 10.6% on average, with permeability of more than 0.3 × 10−3 μm2 accounting for 36% and good reservoir conditions [2,6,9,10].
At the same time, a large number of oolites have developed in bauxite rocks. According to their particle size, these grains can be divided into bean grains (or giant oolitic grains, generally larger than 2 mm in size) and oolitic grains (generally less than 2 mm in size), all of which are spherical structures. These grains are collectively referred to as oolites in this paper. What is the relationship between oolites and reservoir space (pores)? What is the significance of the geological conditions for oolite formation in oil and gas reservoirs? While these questions are crucial for oil and gas exploration, few scholars have explored this field from a microscopic point of view, especially considering oolites.
In this study, data from previous studies are systematically collected. Taking the bauxite series in the Longdong area as an example, the petrology, mineralogy, oolitic micro-morphology, chemical composition, and other sedimentary characteristics of the bauxite series are analyzed using field outcrops, core observations, rock slices, cast slices, X-ray diffraction analysis (XRD), scanning electron microscope–energy dispersive spectroscopy (SEM-EDS), and so on. The micro-characteristics of the factors controlling the formation of bauxite reservoirs and the significance of oil and gas reservoirs are explored from an oolitic perspective, providing a foundation for bauxite reservoir research and theoretical support for bauxite gas reservoir exploration.

2. Regional Geology

The study area is located in the western and southern parts of the North China Craton (NCC) (Figure 1) and developed on the crystalline basement of the Archean–Early Proterozoic boundary [13]. The early Paleozoic was a stable craton basin evolution stage influenced by the Qilian–Qinling Ocean and developed a central paleo-uplift [14,15,16]. The Longdong area was located in the northeastern portion of this large central paleo-uplift during the Early Paleozoic. Due to the influence of Caledonian movement in the Late Ordovician, the study area was uplifted as a whole [17], with sedimentary discontinuities of about 140 Ma. In addition, the sedimentary strata from the Silurian to Early Carboniferous were found to be missing. Since the late Carboniferous, the study area has again experienced overall subsidence and sedimentation due to the southward compression of the Eurasian plate and the closure of the Mongolian Ocean, developing a widely distributed set of bauxite series [18,19,20,21].

3. Sample Collection and Experimental Methods

In this study, we collected core samples of bauxite series from wells L58 and L47-1C in the Longdong area, Ordos Basin (Figure 1), along with 136 sample data on boreholes and profiles from previous studies reporting related results in the Ordos Basin (Table 1). The rock thin section identification method was used to analyze and study the area’s petrological characteristics; this was completed at the Henan Key Laboratory of Biogenic Traces and Sedimentary Minerals, Henan Polytechnic University, Jiaozuo, China. The instrument was a DM4P polarizing microscope manufactured by Leica, Wetzlar, Germany. Microscopic detection of oolitic particles was completed at the National Engineering Laboratory for the Exploration and Development of Low Permeability Oil and Gas Fields. The instruments used for this purpose were a Quanta FEG 450 field emission scanning electron microscope from FEI and a Quantax 200 X-ray energy spectrometer from BRUKER (Billerica, MA, USA). The resolution of the host was set to 1.0 nm@30 kV (SE); the magnification was 200,000–1,000,000; the test voltage was 200 V to 30 kV; and the moving range of the sample table was X = 100 mm, Y = 100 mm, Z = 60 mm, T = −5 to +70°, and R = 360° continuous rotation. The XRD sample test was completed at the Henan Key Laboratory of Biogenic Traces and Sedimentary Minerals, Henan Polytechnic University, Jiaozuo, China. The instruments included a D8 Advance X-diffractometer and CuKα alpha target from Brooke AXS in Germany. The test voltage was 40 kV, the test current was 25 mA, and the scanning width was 3–90°. In addition, the scanning mode was set to continuous scanning, the divergence slit size was 0.6°, the acceptance slit size was 0.1 mm, and the measurement temperature was 25 °C. Before testing, the sample was ground to a 200 mesh size. For specific testing methods and parameters, please refer to the quantitative analysis method for rock minerals using the X-ray energy spectrum (EDS) (SYT 6189-2018) [22] and the analysis method for clay minerals and ordinary non-clay minerals in rocks via X-ray diffraction (SYT 5163-2018) [23].

4. Results and Discussion

4.1. Petrological Characteristics

According to field profile observations, core observations, and thin section identification, the lithology of the bauxite series presents a three-stage structure: bauxitic mudstone is mainly contained in the upper and lower parts, with bauxite series developed in the middle part (Figure 2). At the same time, the area’s lithology also shows cyclicity (Table 2).
Oolite-rich bauxite is generally located in the middle of the bauxite series and is light grey in color. Compared with the lower gray-black bauxitic mudstone, the compactness of this layer is poor, with pores visible inside the oolitic and clastic structures (Figure 3a,b). These pores serve as the main reservoir spaces for bauxite reservoirs.

4.2. Mineralogical Characteristics

Based on the XRD analysis combined with thin section identification and the in situ analysis of scanning electron microscope (SEM) images, the mineral composition of the bauxite series can be divided into four categories: aluminum minerals (Figure 4a), clay minerals (Figure 4b,c), titanium minerals, and other minerals (Table 2).
Figure 5 shows that there is little difference in the composition of similar minerals on the same horizon. However, there are obvious differences in mineral composition on different horizons. These differences indicate that illite and kaolinite are the main minerals in the lower bauxite mudstone, diaspore is the main mineral in the middle bean oolitic bauxite, and kaolinite is the main mineral in the upper bauxitic mudstone.

4.3. Microscopic Characteristics

4.3.1. Oolitic Characteristics

Oolites are mostly round or elliptical with different particle sizes and generally less than 3 cm in diameter. According to their density and degree of mineral crystallization, oolites can be divided into two categories. In the first type, there are many dense layers with more than ten layers composed of dark- and light-colored minerals. These minerals are dark in color, poor in mineral crystallization, and large in particle size; they also present significant shear plastic deformation (Figure 6a). The other type includes a few sparse layers (generally only three) composed of dark- and light-colored minerals, with different colors, good mineral crystallization, and weak shear plastic deformation (Figure 6b).
The ring structures of most oolites are obvious (Figure 7a). Through local amplification and scanning analysis of the energy spectrum distribution, we found that the chemical composition mainly features O, Al, and Si (Figure 7c–h). Moreover, the ring structure is caused by differences in composition, which can also be verified by the results of the energy spectrum analysis.

4.3.2. Oolitic Pores

Bauxite pores in the outcrop profile and core are generally present in the study area. Observing the cast slice using a scanning electron microscope and other techniques indicated a clear dissolution phenomenon. Generally, oolitic pores in the area are about 8–200 μm in size and irregularly shaped (Figure 8a,b), showing obvious leaching characteristics. After the oolites are dissolved, the subsequent solution migrates to the dissolution space to form clay or aluminum minerals in the reducing environment (Figure 8a). The oolites are semi-filled or filled. When the oolites are not filled, dissolution pores develop in the oolites or debris (Figure 8c). Due to the poor crystallization and small crystals in the clay minerals formed during later periods, intergranular pores developed in the filled oolites or debris. The intergranular dissolved pores are small, about 3 μm, and irregularly shaped (Figure 8b,c). The dissolved pores of the granules are generally distributed in the particles, with uneven sizes ranging from 6 to 95 μm (Figure 8c). The intergranular dissolved pores are distributed between the oolites, with sizes exceeding 1 mm. Fractures occasionally occur, which play a certain role in connecting pores but are not the main reservoir space. Instead, dissolved pores provide the main space for bauxite reservoirs.

4.3.3. Porosity and Permeability Characteristics

We obtained 181 porosity readings from reservoir samples in the study area (based only on the number of samples specified in the analysis data) [2,6,7,8,12,24,25]. Porosity ranged from 0.2% to 29.7% and was generally greater than 10%. We also obtained 173 permeability samples, with the permeability ranging from 0.004 × 10−3 μm2 to 38.55 × 10−3 μm2, whose average permeability was generally greater than 4 × 10−3 μm2. Additionally, the reservoir conditions were found to be good, with conditions in oolitic bauxite reservoirs generally better than those of other reservoirs.
The logging and core physical property testing data indicate that the porosity and permeability curves are consistent and have similar variation patterns across the overall profile. There is also a clear positive correlation between porosity and permeability, especially in the oolitic bauxite reservoirs. The porosity and permeability of the bauxitic mudstone in the upper and lower parts are very low, while the porosity and permeability of the oolitic bauxite reservoirs are very high. The physical property tests achieved values of 27.6% and 20.18 × 10−3 μm2 for porosity and permeability, respectively, far exceeding the corresponding values of the Upper Paleozoic sandstone and Lower Paleozoic carbonate rock.

4.4. Brittleness Index

The fracturing ability of the reservoir, i.e., the brittleness index of the reservoir, is one of the most important parameters to be evaluated in later reconstructions of the reservoir. The higher the brittleness index, the more favorable it is for subsequent fracturing of the reservoir [6,26,28]. The reservoir brittleness index is generally calculated using the mineralogical method. The main minerals in the bauxite series are diaspore and clay minerals, so the brittleness index of the bauxite series can be calculated according to Formula (1), that is, the diaspore can be calculated based on brittle minerals [6]. According to the calculation, the brittleness index of the study area can reach 99.3%. The brittleness index of well HT2 is 56.5% to 93.7%, while that of well L58 is 16.4% to 99.3% (Figure 9) [2,4,6,26].
B r i t t l e n e s s   I n d e x = w d i a s p o r e + w q u a r t z w d i a s p o r e + w q u a r t z + w C a r b o n a t e   m i n e r a l s + w c l a y   m i n e r a l s 100 %
Importantly, the brittleness index reflects the fracturing quality of the reservoir, which affects the difficulty of fracturing, among other factors. The higher the brittleness index, the more complex the fracture network that will be formed. The brittleness index of the bauxite series in the study area is high overall. Most notably, the average content of oolitic bauxite (a brittle mineral) in well L58 is 90.82% (Table 2, Figure 4 and Figure 5). About 50% of the samples in these oolitic series have a brittleness index exceeding 95%. Mechanical rock experiments also show that the bauxite series have the characteristics of Young’s modulus (36.4 GPa) and Poisson’s ratio (0.35) [6], which meet the standards of reservoirs rich in brittle minerals and are suitable for the subsequent fracturing and exploitation of natural gas reservoirs. These factors are conducive to improving the initial single-well productivity.

4.5. Influence of Geological Processes on Reservoir Space

The bauxite rock series in the Longdong area is a product of strong chemical weathering and laterization of the original rocks [2,4]. The mineral composition and structures of the original rocks have been thoroughly transformed. The formation of bauxite involves a process of rich iron and aluminum mineralization, as well as the formation of oolites [18,20]. Studies have confirmed that bauxite series are formed under warm/high temperatures in humid/rainy climates [18,19,21,29,30,31,32,33,34,35,36,37,38]. During the Middle Carboniferous, the NCC (where the study area is located) became separated from the Gondwana continent and drifted to the area near the equator, yielding a high temperature and rainy climate [29,39,40,41]. Under these climatic conditions, the chemical weathering degree of parent rocks is strong, which provides a sufficient supply of aluminum-bearing materials and parent materials for oolitic formation in the study area [42].
According to the zircon geochronology, regional structure, and stratigraphy, transgression occurred during the formation of the bauxite series [19,20,21,29,30,31,32,33,34,35,36,37,38]. The Ordos Basin was affected by the central paleo-uplift [14,15,16], and its eastern part was a limited epicontinental sea [7], which belonged to a typical subtidal low-energy sedimentary environment. Due to the hydrodynamic conditions, aluminum-bearing minerals here mostly feature clastic and oolitic structures, with oolites widely distributed.
Due to the effect of the central paleo-uplift and the existence of the ancient Qingyang land, the bauxite series were transported to the lower part of the paleogeomorphology, thereby enriching the material basis of oolitic ore-forming materials due to the low and relatively closed terrain [7]. At the same time, the relatively low paleogeomorphology facilitated surface water leaching, with high karstification intensity [33,41]. Consequently, the soluble components in the area were more easily lost, and leaching led to the formation of minerals such as boehmite (Table 2, Figure 4 and Figure 5) and the development of a large number of oolites.
The pores in the bauxite series were generated during the intense chemical weathering processes of the original rock, which were closely related to physical and chemical factors. Pores formed through physical processes are often modified by later chemical reactions. As mentioned previously, a large number of oolitic pores developed relatively deep into the paleogeomorphology, providing more space for the reservoir. Indeed, the pores in the bauxite series are closely related to the formation process of the bauxite series, whose pore formation and storage were primarily informed by related chemical processes. The types of pores formed were primarily dissolution pores and intergranular pores. Therefore, the sedimentary paleogeomorphology of the Ordos Basin controls the quality of the Paleozoic bauxite reservoirs in the Longdong area.
In the Early Paleozoic, the whole study area existed in a stable craton evolution stage. By the late Cambrian, the Qingyang area was uplifted to form a paleocontinent, which established the regional tectonic background of the Longdong area located in a large central paleo uplift [14,15]. Since the Middle Ordovician, the study area has experienced an overall uplift through Caledonian tectonic movement, resulting in sedimentary discontinuity and stratigraphic loss. In the late Paleozoic, the craton depression structure settled steadily, and frequent transgression occurred, leading to thicker coal seams and carbonaceous mudstone deposits in the upper part of the bauxite series. The humic acid formed in the diagenetic process further reformed the bauxite reservoir and promoted the development of numerous dissolution pores in the bauxite reservoir [43].
Comparing and analyzing the carbon isotope data of natural gas in various gas strata of the Paleozoic indicates that the bauxite, Shihezi Formation tight sandstone, and pre-Carboniferous weathered crust gas reservoirs are homologous. These reservoirs were primary formed from Upper Paleozoic coal measure hydrocarbon source rocks [7,44,45]. Upper Paleozoic coal measure source rocks are widely distributed and have a high thermal evolution degree. These rocks also offer strong hydrocarbon generation capabilities, which can produce sufficient gas resources for the Paleozoic bauxite gas reservoir [7].
The coal seam and carbonaceous mudstone in the upper part of the bauxite series are not only superior source rocks but also good sealing layers, forming a source reservoir configuration with “upper generation and lower storage”. The bauxite series in the study area features a gas reservoir combining source storage and sealing [2,7]. The development of faults and fractures during the Indosinian period effectively connected the Shanxi Formation source rocks with bauxite reservoirs, diverted oil and gas, and facilitated oil and gas accumulation. Therefore, the bauxite series in the study area generally contain significant gas content. However, the formation of the aforementioned oolitic mineral series (or the intensity of aluminum enrichment or chemical weathering) is closely related to the drainage conditions of karst processes. The bauxite series appears most developed at the karst funnel and is positively correlated with the depth of the funnel. Paleokarstification of the ancient rock also controls the planar distribution of the bauxite series.

5. Conclusions

  • The lithology of the bauxite series was mainly bauxite and bauxitic mudstone, and the mineral composition was mainly aluminum minerals, clay minerals, titanium minerals, and other minerals. The content of boehmite in oolites ranged from 73.5% to 96.5%, with an average of 90.82%. The ring structures of most oolites were obvious and caused by differences in composition.
  • Oolite-rich bauxite with corrosion pores and intercrystalline pores about 8–20 μm in size was most common. The dissolved pores provided the main reservoir space for the bauxite reservoirs. The brittleness index was high, making the area suitable for subsequent fracturing of natural gas reservoirs.
  • The main gas source rocks for the oolitic bauxite rock and Paleozoic gas series were coal measure source rocks of the Upper Paleozoic. The oolitic bauxite reservoirs generally contained obvious gas content, but the continuity of the planar distribution was poor.

Author Contributions

Conceptualization, F.S. and Z.W.; methodology, F.S. and G.C.; investigation, X.S., S.L., Z.L., X.M., X.Z. and S.Z.; resources, L.X. and X.S.; data curation, C.Q., L.Z. and L.X.; writing—original draft preparation, F.S., C.Q. and G.C.; writing—review and editing, F.S. and G.C.; funding acquisition, F.S. and G.C. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Key Research and Development Special Project of Henan Province (Grant No. 231111320700), the Key Research Projects of Higher Education Institutions in Henan Province (Grant No. 23A170004), the Natural Science Foundation of Henan Province (No. 232300420168), and the Doctoral Foundation of Henan Polytechnic University (Grant No. B2021-77).

Data Availability Statement

The data that support the findings of this study are available from the corresponding author upon reasonable request.

Acknowledgments

The authors thank Pan Jianyun, General Manager of Luanchuan Hengyu Mining Co., Ltd., and graduated master’s students Xing Zhou, Fang Bangbang, and Yu Shuangjie for their assistance in the fieldwork.

Conflicts of Interest

Authors Shengtao Luo and Zhuang Liu were employed by the company Luanchuan Hengyu Mining Co., Ltd. Authors Liqin Xie and Xiaohu Shi were employed by the Exploration and Development Research Institute of Changqing 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.

References

  1. Li, Y.; Wang, Z.; Shao, L.; Gong, J.; Wu, P. Reservoir characteristics and formation model of Upper Carboniferous bauxite series in eastern Ordos Basin, NW China. Pet. Explor. Dev. Online 2024, 51, 44–53. [Google Scholar] [CrossRef]
  2. Yao, J.; Shi, X.; Yang, W.; Zhang, L.; Xie, L.; An, W.; Wang, H.; Zhang, R. Reservoir characteristics and exploration significance of the bauxite rock series of Permian Taiyuan formation in the Longdong area of the Ordos Basin. Acta Sedimentol. Sin. 2023, 41, 1583–1597. [Google Scholar]
  3. Li, H.; Fu, J.; Ji, H.; Zhang, L.; Yu, Y.; Guan, W.; Jing, X.; Wang, H.; Cao, Q.; Liu, G.; et al. Bauxite series in the Upper Paleozoic weathering crusts in the southwestern Ordos Basin: Development and distribution of dominant reservoirs. Oil Gas Geol. 2023, 44, 1243–1255. [Google Scholar]
  4. Xie, L.; Li, M.; Yang, W.; Ma, Z.; Wang, H. Studies on micro-mineral geological characteristics of aluminum bearing rock series of Taiyuan Formation in Longdong area, Ordos Basin. Nat. Gas Geosci. 2024, 35, 1363–1374. [Google Scholar]
  5. Zhang, P.; Jing, X.; Pu, R.; Wang, A.; Huang, X. Logging identification and distribution of bauxite in the southwest ordos basin. Minerals 2023, 13, 1253. [Google Scholar] [CrossRef]
  6. Nan, J.; Liu, N.; Wang, X.; Wei, G.; Yin, P.; Yang, Y. Characteristics and formation mechanism of bauxite reservoir in Taiyuan Formation, Longdong area, Ordos Basin. Nat. Gas Geosci. 2022, 33, 288–296. [Google Scholar]
  7. Fu, J.; Li, M.; Zhang, L.; Cao, Q.; Wei, X. Breakthrough in the exploration of bauxite gas reservoir in Longdong area of the Ordos Basin and its petroleum geological implications. Nat. Gas Ind. 2021, 41, 1–11. [Google Scholar]
  8. Zhang, L.; Cao, Q.; Zhang, C.; Zhang, J.; Wei, J.; Li, H.; Wang, X.; Pan, X.; Yan, T.; Quan, H. Main controlling factors and exploration enlightenment of aluminous rock series gas reservoirs in Ordos Basin, NW China. Pet. Explor. Dev. Online 2024, 51, 621–633. [Google Scholar] [CrossRef]
  9. Yu, S.; Zhao, Z.; Zhu, Y.; Zhu, X.; Lai, J.; Li, D.; Wang, X. Reservoir characteristics and formation model of the bauxite gas reservoir: The benxi formation in the lx block, northeast of Ordos Basin, China. ACS Omega 2024, 9, 18127–18136. [Google Scholar] [CrossRef]
  10. Wang, Y.; Guo, J.; Zhou, L.; Ma, Z.; Liu, Z.; Bai, Y.; Che, X. Characteristics and an accumulation model of a bauxite gas reservoir in the southwestern Ordos Basin. Mar. Pet. Geol. 2024, 166, 106916. [Google Scholar] [CrossRef]
  11. Liu, D.; Zhang, H.; Yang, X.; Zhao, T.; Kou, X.; Zhu, B. Well Logging Evaluation of Bauxite Reservoirs in Ordos Basin. Xinjiang Pet. Geol. 2022, 43, 261–270. [Google Scholar]
  12. Zhang, W.; Zhang, C.; Liu, Y.; Zhu, G.; Hu, Y.; Li, N. Mud logging evaluation of bauxite reservoir in Taiyuan Formation, Longdong area, Ordos Basin. Mud Logging Eng. 2022, 33, 41–48. [Google Scholar]
  13. Zhai, M.; Santosh, M. The early Precambrian odyssey of the North China Craton: A synoptic overview. Gondwana Res. 2011, 20, 6–25. [Google Scholar] [CrossRef]
  14. He, D.; Bao, H.; Sun, F.; Zhang, C.; Kai, B. Geologic structure and genetic mechanism for the central uplift in the Ordos Basin. Chin. J. Geol. 2020, 55, 627–656. [Google Scholar]
  15. Huang, J.; Zheng, C.; Zhang, J. Origin of the central paleo uplift in Ordos Basin. Nat. Gas Ind. 2005, 25, 23–26. [Google Scholar]
  16. Xie, G.; Zhang, Q.; Guo, L. The genesis and hydrocarbon distribution of western and southern margins of Paleozoic foreland basin and central paleo uplift in Ordos Basin. Acta Petrol. Sin. 2003, 24, 18–23+29. [Google Scholar]
  17. Xiao, W.; Windley, B.; Sun, S.; Li, J.; Han, B.; Han, C.; Yuan, C.; Sun, M.; Chen, H. A tale of amalgamation of three permo-triassic collage systems in central Asia: Oroclines, sutures, and terminal accretion. Annu. Rev. Earth Planet. Sci. 2015, 43, 477–507. [Google Scholar] [CrossRef]
  18. Sun, F.; Cao, G. Provenance of bauxite and clay deposits in the carboniferous Benxi formation, Western Henan, China: Constraints from U–pb geochronology and regional geology. Geol. J. 2022, 57, 3090–3100. [Google Scholar] [CrossRef]
  19. Wang, Q.; Deng, J.; Liu, X.; Zhao, R.; Cai, S. Provenance of late carboniferous bauxite deposits in the North China Craton: New constraints on marginal arc construction and accretion processes. Gondwana Res. 2016, 38, 86–98. [Google Scholar] [CrossRef]
  20. Sun, F. Study on Provenance and Aluminum Enrichment of the Benxi Formation in the Southeastern Part of North China Block. Ph.D. Thesis, Henan Polytechnic University, Jiaozuo, China, 2019. [Google Scholar]
  21. Liu, X.; Wang, Q.; Feng, Y.; Li, Z.; Cai, S. Genesis of the guangou karstic bauxite deposit in western henan, China. Ore Geol. Rev. 2013, 55, 162–175. [Google Scholar] [CrossRef]
  22. SY/T 6189—2018; National Energy Administration. Quantitative Analysis Method of Rock Mineral Energy. Petroleum Industry Press: Beijing, China, 2018.
  23. SY/T 5163—2018; National Energy Administration. Analysis Method for Clay Minerals and Ordinary Non-Clay Minerals in Rocks by the X-ray Diffraction. Petroleum Industry Press: Beijing, China, 2018.
  24. Wu, J.; Yang, H.; Xu, Y.; Jiang, Q.; Yuan, Y.; Fu, H.; Wang, X.; Pang, Z.; Wu, P. Reservoir characteristics and development control factors of Benxi Formation bauxite in Linxing area of Ordos Basin. Bull. Geol. Sci. Technol. 2024, 1–13, pre-pub online. [Google Scholar]
  25. Peng, S.; Zhao, J.; Xie, G.; Xu, X.; Zhang, J.; Zhang, L.; Li, N.; Li, W.; Hu, X.; Wei, K. Characteristics and formation mechanism of bauxite reservoir in Benxi formation, Northeast Ordos Basin. Mineral. Petrol. 2024, 1–14. [Google Scholar]
  26. Xu, X.; Lu, H.; Wang, W.; Ye, L.; Wang, L.; Wu, Y.; Zhao, Q. Effective hydraulic fracturing of the bauxite rock series in the Longdong area, Ordos Basin. Nat. Gas Geosci. 2024, 35, 1488–1501. [Google Scholar]
  27. Liu, D.; Zhou, J.; Zhang, X.; Wu, Y.; Zhao, T.; Tian, L.; Yang, M. Study on lithofacies log identification and favorable lithofacies distribution of new types of bauxite reservoirs in Ordos Basin. Nat. Gas Geosci. 2023, 35, 1441–1453. [Google Scholar]
  28. Zhang, C.; Wang, Y.; Dong, D.; Li, X.; Guan, Q. Evaluation of the Wufeng-Longmaxi shale brittleness and prediction of “sweet spot layers” in the Sichuan Basin. Nat. Gas Ind. 2016, 36, 51–60. [Google Scholar]
  29. Yu, W.; Algeo, T.J.; Yan, J.; Yang, J.; Du, Y.; Huang, X.; Weng, S. Climatic and hydrologic controls on upper paleozoic bauxite deposits in South China. Earth-Sci. Rev. 2019, 189, 159–176. [Google Scholar] [CrossRef]
  30. Zhao, L.; Liu, X. Metallogenic and tectonic implications of detrital zircon u–pb, hf isotopes, and detrital rutile geochemistry of late carboniferous karstic bauxite on the southern margin of the North China Craton. Lithos 2019, 350–351, 105222. [Google Scholar] [CrossRef]
  31. Cai, S.; Wang, Q.; Liu, X.; Feng, Y.; Zhang, Y. Petrography and detrital zircon study of late carboniferous sequences in the southwestern North China Craton: Implications for the regional tectonic evolution and bauxite genesis. J. Asian Earth Sci. 2015, 98, 421–435. [Google Scholar] [CrossRef]
  32. Zhang, C.; Pu, C.; Cao, R.; Jiang, T.; Huang, G. The stability and roof-support optimization of roadways passing through unfavorable geological bodies using advanced detection and monitoring methods, among others, in the sanmenxia bauxite mine in china’s henan province. Bull. Eng. Geol. Environ. 2019, 78, 5087–5099. [Google Scholar] [CrossRef]
  33. Du, Y.; Yu, W. Subaerial leaching process of sedimentary bauxite and the discussion on classifications of bauxite deposits. J. Palaeogeogr. 2020, 22, 812–826. [Google Scholar]
  34. Cao, G.; Liu, L.; Xing, Z.; Sun, F.; Yu, S.; Fang, B.; Du, X.; Zhou, H.; Chen, Y. Material sources analysis of karstic bauxite of Benxi formation in Gongyi area, Henan Province: Evidences from LA-ICP-MS U-Pb dating of detrital zircons. J. Henan Polytech. Univ. (Nat. Sci.) 2018, 37, 55–65. [Google Scholar]
  35. Wang, Y.; Zhou, L.; Zhao, L.; Ji, M.; Gao, H. Palaeozoic uplands and unconformity in the North China Block: Constraints from zircon LA-ICP-MS dating and geochemical analysis of bauxite. Terra Nova 2010, 22, 264–273. [Google Scholar] [CrossRef]
  36. Yu, W.; Algeo, T.J.; Du, Y.; Zhang, Q.; Liang, Y. Mixed volcanogenic–lithogenic sources for Permian bauxite deposits in southwestern Youjiang basin, South China, and their metallogenic significance. Sediment. Geol. 2016, 341, 276–288. [Google Scholar] [CrossRef]
  37. Wang, Q.; Liu, X.; Yan, C.; Cai, S.; Li, Z.; Wang, Y.; Zhao, J.; Li, G. Mineralogical and geochemical studies of boron-rich bauxite ore deposits in the Songqi region, SW Henan, China. Ore Geol. Rev. 2012, 48, 258–270. [Google Scholar] [CrossRef]
  38. Liu, X.; Wang, Q.; Zhao, L.; Peng, Y.; Ma, Y.; Zhou, Z. Metallogeny of the large-scale carboniferous karstic bauxite in the Sanmenxia area, southern part of the North China Craton, China. Chem. Geol. 2020, 556, 119851. [Google Scholar] [CrossRef]
  39. Wang, P.; Du, Y.; Yu, W.; Algeo, T.J.; Zhou, Q.; Xu, Y.; Qi, L.; Yuan, L.; Pan, W. The chemical index of alteration (CIA) as a proxy for climate change during glacial-interglacial transitions in Earth history. Earth-Sci. Rev. 2020, 201, 103032. [Google Scholar] [CrossRef]
  40. Xue, G.; Li, Z.; Guo, W.; Fan, J. The exploration of sedimentary bauxite deposits using the reflection seismic method: A case study from the henan province, china. Ore Geol. Rev. 2020, 127, 103832. [Google Scholar] [CrossRef]
  41. Weng, S.; Yu, W.; Algeo, T.J.; Du, Y.; Li, P.; Lei, Z.; Zhao, S. Giant bauxite deposits of south china: Multistage formation linked to late paleozoic ice age (lpia) eustatic fluctuations. Ore Geol. Rev. 2019, 104, 1–13. [Google Scholar] [CrossRef]
  42. Zhang, Y.; Zhang, Y.; Wu, H.; Ding, X.; Ling, W.; Lei, Z.; Wen, S.; Ma, Q.; Du, Y. Microscopic geochemical characteristics of oolite in oolitic bauxite ores from Wuchuan-Zheng’an-Daozhen area in the northern Guizhou Province and their metallogenic significance. Geol. Sci. Technol. Inf. 2013, 32, 62–70. [Google Scholar]
  43. Dai, J.; Xia, X.; Qin, S.; Zhao, J. Origins of partially reversed alkane δ13C values for biogenic gases in China. Org. Geochem. 2004, 35, 405–411. [Google Scholar] [CrossRef]
  44. Ouyang, Z.; Wang, H.; Sun, B.; Liu, Y.; Fu, X.; Dou, W.; Du, L.; Zhang, B.; Luo, B.; Yang, M.; et al. Quantitative Prediction of Deep Coalbed Methane Content in Daning-Jixian Block, Ordos Basin, China. Processes 2023, 11, 3093. [Google Scholar] [CrossRef]
  45. Sun, J.; Chen, M.; Wang, B.; Wang, G.; Tian, H.; Hou, J.; Zhu, B. Analysis of Factors Influencing Tight Sandstone Gas Production and Identification of Favorable Gas Layers in the Shan 23 Sub-Member of the Daning-Jixian Block, Eastern Ordos Basin. Processes 2024, 12, 1810. [Google Scholar] [CrossRef]
Processes 12 02123 g001
Figure 1. Geological sketch map showing sample locations [18].
Figure 1. Geological sketch map showing sample locations [18].
Processes 12 02123 g001
Processes 12 02123 g002
Figure 2. Core histogram of the bauxite series in well L58 [2]. (a) Sandstone; (b) Carbonaceous mudstone; (c) bauxitic mudstone; (d) bauxite rock; (e) dolomite.
Figure 2. Core histogram of the bauxite series in well L58 [2]. (a) Sandstone; (b) Carbonaceous mudstone; (c) bauxitic mudstone; (d) bauxite rock; (e) dolomite.
Processes 12 02123 g002
Processes 12 02123 g003
Figure 3. Lithological characteristics of the oolitic bauxite series. (a) Pores in the oolitic bauxite of the middle part, well L47-1C, 4151.60 m; (b) pores in the oolitic bauxite of the middle part, well L58, 4049.50 m; (c) massive pyrite in the oolitic bauxite of the middle part, well L47-1C, 4149.75 m; (d) uneven distribution of bauxite and siderite detritus in the oolitic bauxite of the middle part, well L47-1C, 4150.70 m; (e) irregular laminae in the oolitic bauxite of the middle part, well L47-1C, 4153.57 m; (f) layered siderite in the bauxitic mudstone, well L47-1C, 4145.92 m; (g) Carbonaceous mudstone in the oolitic bauxite of the middle part, well L47-1C, 4153.93 m; (h) abrupt contact relationship between the oolitic bauxite of the middle part and the bauxitic mudstone in the upper side, well L47-1C, 4149.10 m; (i) small siderite oolitic grains in the bauxitic mudstone, well L47-1C, 4148.81 m.
Figure 3. Lithological characteristics of the oolitic bauxite series. (a) Pores in the oolitic bauxite of the middle part, well L47-1C, 4151.60 m; (b) pores in the oolitic bauxite of the middle part, well L58, 4049.50 m; (c) massive pyrite in the oolitic bauxite of the middle part, well L47-1C, 4149.75 m; (d) uneven distribution of bauxite and siderite detritus in the oolitic bauxite of the middle part, well L47-1C, 4150.70 m; (e) irregular laminae in the oolitic bauxite of the middle part, well L47-1C, 4153.57 m; (f) layered siderite in the bauxitic mudstone, well L47-1C, 4145.92 m; (g) Carbonaceous mudstone in the oolitic bauxite of the middle part, well L47-1C, 4153.93 m; (h) abrupt contact relationship between the oolitic bauxite of the middle part and the bauxitic mudstone in the upper side, well L47-1C, 4149.10 m; (i) small siderite oolitic grains in the bauxitic mudstone, well L47-1C, 4148.81 m.
Processes 12 02123 g003
Processes 12 02123 g004
Figure 4. Mineral characteristics of oolitic bauxite series in the Longdong area. (a) Microcrystalline characteristics of diaspore (−), well L47-1C, 4155.36 m; (b) microscopic characteristics of illite (−), well L47-1C, 4155.36 m; (c) kaolinite microscopic characteristics (−), well L47-1C, 4152.46 m. m-Dia-diaspore microcrystals; Dia-diaspore; m-Ill-illite microcrystals; Ill-illite; Kao-kaolinite.
Figure 4. Mineral characteristics of oolitic bauxite series in the Longdong area. (a) Microcrystalline characteristics of diaspore (−), well L47-1C, 4155.36 m; (b) microscopic characteristics of illite (−), well L47-1C, 4155.36 m; (c) kaolinite microscopic characteristics (−), well L47-1C, 4152.46 m. m-Dia-diaspore microcrystals; Dia-diaspore; m-Ill-illite microcrystals; Ill-illite; Kao-kaolinite.
Processes 12 02123 g004
Processes 12 02123 g005
Figure 5. Variation characteristics of mineral composition in Well L58 (XRD analysis). The data sources are the test results and references [2,4].
Figure 5. Variation characteristics of mineral composition in Well L58 (XRD analysis). The data sources are the test results and references [2,4].
Processes 12 02123 g005
Processes 12 02123 g006
Figure 6. Oolitic characteristics of bauxite series in the Longdong area. (a) Oolite with multiple layers, strong plastic deformation, ring zone is reformed by the oolite with fewer ring layers, well L47-1C, 4150.00 m (single polarized light); (b) oolite with few unformed ring layers, well L47-1C, 4150.00 m (single polarized light).
Figure 6. Oolitic characteristics of bauxite series in the Longdong area. (a) Oolite with multiple layers, strong plastic deformation, ring zone is reformed by the oolite with fewer ring layers, well L47-1C, 4150.00 m (single polarized light); (b) oolite with few unformed ring layers, well L47-1C, 4150.00 m (single polarized light).
Processes 12 02123 g006
Processes 12 02123 g007
Figure 7. Microscopic characteristics of oolites (well L58, 4042.97 m). The left images (a,b) and (g) are SEM images, and the right images (cf,h) are EDS images.
Figure 7. Microscopic characteristics of oolites (well L58, 4042.97 m). The left images (a,b) and (g) are SEM images, and the right images (cf,h) are EDS images.
Processes 12 02123 g007
Processes 12 02123 g008
Figure 8. Dissolution phenomenon of oolitic bauxite series in the Longdong area. (a) Oolite is dissolved and filled with kaolinite, well L47-1C, 4150.24 m (+); (b) multi-stage dissolution in the oolite, intergranular pores developed between kaolinite crystals, well L47-1C, 4155.36 m (+); (c) siderite in the oolite is not completely dissolved, flaky chlorite is filled, intergranular pores are developed, well L47-1C, 4152.94 m, (EDT image). Kao-kaolinite; m-Dia-diaspore microcrystals; Sid-siderite; Chl-chlorite.
Figure 8. Dissolution phenomenon of oolitic bauxite series in the Longdong area. (a) Oolite is dissolved and filled with kaolinite, well L47-1C, 4150.24 m (+); (b) multi-stage dissolution in the oolite, intergranular pores developed between kaolinite crystals, well L47-1C, 4155.36 m (+); (c) siderite in the oolite is not completely dissolved, flaky chlorite is filled, intergranular pores are developed, well L47-1C, 4152.94 m, (EDT image). Kao-kaolinite; m-Dia-diaspore microcrystals; Sid-siderite; Chl-chlorite.
Processes 12 02123 g008
Processes 12 02123 g009
Figure 9. Characteristics of brittleness index. (a) Well HT2; (b) Well L58. The data sources are the test results and references [2,4,6,26].
Figure 9. Characteristics of brittleness index. (a) Well HT2; (b) Well L58. The data sources are the test results and references [2,4,6,26].
Processes 12 02123 g009
Table 1. Data on boreholes and profiles of previous studies on related achievements in the study area.
Table 1. Data on boreholes and profiles of previous studies on related achievements in the study area.
NumberBorehole/PositionQuantityAuthorsNotes
1L5813Yao et al.[2]
2L474Nan et al.[6]
3L583Nan et al.[6]
4L5814Liu et al.[11]
5C34Liu et al.[11]
6HT23Liu et al.[11]
7Eastern Ordos Basin17Li et al.[1]
8Linxing area16Wu et al.[24]
9Northeastern Ordos Basin11Peng et al.[25]
10L583Xu et al.[26]
11HT27Xu et al.[26]
12HT11Xu et al.[26]
13L5819Xie et al.[4]
14Longdong21Liu et al.[27]
Total 136
Table 2. XRD analysis results of the samples in well L58.
Table 2. XRD analysis results of the samples in well L58.
Depth (m)LithologyBoehmiteClayOtherNotes
4040.00 bauxitic mudstone3.194.32.6
4040.12 bauxitic mudstone0.9945.1
4040.62 bauxitic mudstone14.374.810.9Repeat
4041.00 bauxitic mudstone18.869.611.6
4041.74 bauxite7816.75.3
4042.54 bauxite9433
4042.82 bauxitic mudstone62.928.28.9Test
4042.82 bauxitic mudstone62.912.824.3Data
4042.97 bauxitic mudstone47.149.33.6
4044.63 bauxitic mudstone2919.851.2
4044.99 bauxite93.64.12.3Repeat
4045.24 bauxite96.11.22.7Repeat
4045.55 bauxite89.72.38
4045.90 bauxite96.41.12.5Repeat
4047.10 bauxite93.10.76.2
4047.10 bauxite93.10.76.2
4047.40 bauxite96.50.92.6
4048.25 bauxite95.41.43.2Repeat
4049.58 bauxite95.60.83.6Repeat
4050.76 bauxite73.518.97.6
4051.10 bauxite85.710.83.5
4051.71 bauxitic mudstone5138.610.4Repeat
4052.20 bauxitic mudstone36.450.613
4052.20 bauxitic mudstone36.440.223.4
4052.39 bauxitic mudstone30.854.814.4
4053.29 bauxitic mudstone16.664.718.7Repeat
4053.99 bauxitic mudstone16.564.818.7
4054.92 bauxitic mudstone20.95722.1
4055.26 bauxitic mudstone4840.711.3
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Sun, F.; Qu, C.; Cao, G.; Xie, L.; Shi, X.; Luo, S.; Liu, Z.; Zhang, L.; Ma, X.; Zhou, X.; et al. Oolitic Sedimentary Characteristics of the Upper Paleozoic Bauxite Series in the Eastern Ordos Basin and Its Significance for Oil and Gas Reservoirs. Processes 2024, 12, 2123. https://doi.org/10.3390/pr12102123

AMA Style

Sun F, Qu C, Cao G, Xie L, Shi X, Luo S, Liu Z, Zhang L, Ma X, Zhou X, et al. Oolitic Sedimentary Characteristics of the Upper Paleozoic Bauxite Series in the Eastern Ordos Basin and Its Significance for Oil and Gas Reservoirs. Processes. 2024; 12(10):2123. https://doi.org/10.3390/pr12102123

Chicago/Turabian Style

Sun, Fengyu, Changling Qu, Gaoshe Cao, Liqin Xie, Xiaohu Shi, Shengtao Luo, Zhuang Liu, Ling Zhang, Xiaochen Ma, Xinhang Zhou, and et al. 2024. "Oolitic Sedimentary Characteristics of the Upper Paleozoic Bauxite Series in the Eastern Ordos Basin and Its Significance for Oil and Gas Reservoirs" Processes 12, no. 10: 2123. https://doi.org/10.3390/pr12102123

APA Style

Sun, F., Qu, C., Cao, G., Xie, L., Shi, X., Luo, S., Liu, Z., Zhang, L., Ma, X., Zhou, X., Zhu, S., & Wang, Z. (2024). Oolitic Sedimentary Characteristics of the Upper Paleozoic Bauxite Series in the Eastern Ordos Basin and Its Significance for Oil and Gas Reservoirs. Processes, 12(10), 2123. https://doi.org/10.3390/pr12102123

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop