Large Coal-Derived Gas Fields and Their Gas Sources in the Sichuan Basin

The Weiyuan (WY) and Changning (CN) fields are the largest shale gas fields in the Sichuan Basin. Though the shale gases in both fields are sourced from the Longmaxi Formation, this study found notable differences between them in molecular composition, carbon isotopic composition, and noble gas abundance and isotopic composition. CO2 (av. 0.52%) and N2 (av. 0.94%) were higher in Weiyuan than in Changning by an average of 0.45% and 0.70%, respectively. The δ13C1 (−26.9% to −29.7%) and δ13C2 (−32.0% to −34.9%) ratios in the Changning shale gases were about 8% and 6% heavier than those in Weiyuan, respectively. Both shale gases had similar 3He/4He ratios but different 40Ar/36Ar ratios. These geochemical differences indicated complex geological conditions and shed light on the evolution of the Lonmaxi shale gas in the Sichuan Basin. In this study, we highlight the possible impacts on the geochemical characteristics of gas due to tectonic activity, thermal evolution, and migration. By combining previous gas geochemical data and the geological background of these natural gas fields, we concluded that four factors account for the differences in the Longmaxi Formation shale gas in the Sichuan Basin: a) A different ratio of oil cracking gas and kerogen cracking gas mixed in the closed system at the high over-mature stage. b) The Longmaxi shales in WY and CN have had differential geothermal histories, especially in terms of the effects from the Emeishan Large Igneous Province (LIP), which have led to the discrepancy in evolution of the shales in the two areas. c) The heterogeneity of the Lower Silurian Longmaxi shales is another important factor, according to the noble gas data. d) Although shale gas is generated in closed systems, natural gas loss throughout geological history cannot be avoided, which also accounts for gas geochemical differences. This research offers some useful information regarding the theory of shale gas generation and evolution.

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Distribution rules, main controlling factors and exploration directions of giant gas fields in the Sichuan Basin

Natural Gas Industry B ◽

10.1016/j.ngib.2020.01.001 ◽

2020 ◽

Vol 7 (1) ◽

pp. 1-12

Author(s):

Guoqi Wei ◽

Wei Yang ◽

Mancang Liu ◽

Wuren Xie ◽

Hui Jin ◽

...

Keyword(s):

Sichuan Basin ◽

Controlling Factors ◽

Distribution Rules ◽

Main Controlling Factors ◽

The Sichuan Basin ◽

Gas Fields

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Optimization techniques for the secondary development of old gas fields in the Sichuan Basin and their application

Natural Gas Industry B ◽

10.1016/j.ngib.2017.05.010 ◽

2016 ◽

Vol 3 (6) ◽

pp. 595-606

Author(s):

Chongshuang Xia ◽

Linqing Liu ◽

Li Zhang ◽

Xian Peng

Keyword(s):

Sichuan Basin ◽

Optimization Techniques ◽

Secondary Development ◽

The Sichuan Basin ◽

Gas Fields

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An overview of the characteristic of typical Wufeng–Longmaxi shale gas fields in the Sichuan Basin, China

Natural Gas Industry B ◽

10.1016/j.ngib.2021.04.001 ◽

2021 ◽

Author(s):

Haikuan Nie ◽

Qian Chen ◽

Guangrong Zhang ◽

Chuanxiang Sun ◽

Pengwei Wang ◽

...

Keyword(s):

Shale Gas ◽

Sichuan Basin ◽

Longmaxi Shale ◽

The Sichuan Basin ◽

Gas Fields

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Sulfate Sources of Thermal Sulfate Reduction (TSR) in the Permian Changxing and Triassic Feixianguan Formations, Northeastern Sichuan Basin, China

Geofluids ◽

10.1155/2019/5898901 ◽

2019 ◽

Vol 2019 ◽

pp. 1-13 ◽

Cited By ~ 2

Author(s):

Pingping Li ◽

Huayao Zou ◽

Fang Hao ◽

Xinya Yu

Keyword(s):

Sulfate Reduction ◽

Sichuan Basin ◽

Sulfur Isotopes ◽

Adjacent Area ◽

Gas Field ◽

Northeastern Part ◽

Solid Bitumen ◽

The Sichuan Basin ◽

Gas Fields ◽

Puguang Gas Field

Thermal sulfate reduction (TSR) occurred throughout the Permian Changxing (P2c) and Triassic Feixianguan (T1f) dolostone reservoirs in the western and eastern parts of the Kaijiang-Liangping (K-L) trough in the northeastern part of the Sichuan Basin. To determine the sulfate sources of this TSR, fourteen solid bitumen samples and eight anhydrite samples were collected from the northeastern part of the Sichuan Basin. These samples were analyzed to determine their sulfur isotopes. In addition, untreated, HNO3-treated, and CrCl2-treated solid bitumen samples were analyzed to determine their sulfur isotopes in order to obtain reliable δ34S data for the TSR solid bitumen. The results show that the HNO3 method is more effective at removing pyrite from solid bitumen than the method using CrCl2 thrice because the HNO3-treated solid bitumen has lower sulfur contents and higher δ34S. The δ34S of the T1f solid bitumen samples from the Puguang gas field (in the eastern part of the K-L trough, 12.0-24.0‰) is significantly lower than that of the samples from the Yuanba gas field (in the western part of the K-L trough, 24.1-34.2‰). The δ34S of the T1f1–2 anhydrite is 18.1-26.6‰, which is lower than that of the T1f3–4 anhydrite samples (29.9-39.6‰). The TSR sulfates from the Puguang gas field were most likely from the coeval T1f1–2 evaporating seawater and were enriched during the reflux-seepage dolomitization process. The TSR sulfates from the Yuanba gas field were primarily caused by the evaporation of seawater during the T1f4. First, the evaporating seawater would flow vertically into the P2c reservoirs in the adjacent area, and then, it would flow laterally into the P2c reservoirs in the Yuanba gas field. Considering the fact that the sulfate sources of TSR and the δ34S values of the TSR sulfates are different in the Puguang and Yuanba gas fields, the δ34S of TSR solid bitumen cannot be simply used to show the extent of TSR.

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Pore Preservation and Failure Mechanism of Sinian Dengying Formation Carbonate Reservoirs: A Case Study of Two Ultradeep Wells in the Sichuan Basin, Western China

Geofluids ◽

10.1155/2021/8387748 ◽

2021 ◽

Vol 2021 ◽

pp. 1-20

Author(s):

Zeqi Li ◽

Wei Sun ◽

Shugen Liu ◽

Zhiwu Li ◽

Bin Deng ◽

...

Keyword(s):

Late Cretaceous ◽

Sichuan Basin ◽

Pressure Coefficient ◽

Carbonate Reservoirs ◽

Western China ◽

Dengying Formation ◽

Contraction Joints ◽

Average Porosity ◽

The Sichuan Basin ◽

Gas Fields

Despite being one of the most important factors in deep oil and gas exploration, the preservation mechanisms of ultradeep carbonate reservoirs remain poorly understood. This study performed thin-section, geochemistry, field emission scanning electron microscopy, fluid inclusion, and basin model analysis of samples from two boreholes over 8,000 m deep in the Sichuan Basin to determine the pore features and preservation mechanism of the Sinian (Ediacaran) Dengying Formation carbonate reservoirs. The reservoir of CS well #1 is characterised by pore diameters larger than a centimetre (average porosity 7.48%; permeability 0.8562 mD), and the pores are mainly filled with dolomite or bitumen. In contrast, the reservoir of MS well #1 is predominantly composed of micron-scale residual pores (average porosity 1.74%; permeability 0.0072 mD), and the pores are typically filled with dolomite, bitumen, and multistage quartz. The burial thermal histories suggest that both reservoirs were subjected to high pressure (i.e., pressure coefficient > 1.5 ) before the Late Cretaceous. However, the pressure coefficient of the reservoir of MS well #1 has decreased to less than 1.0 owing to strong structural adjustment this well since the Late Cretaceous, which allowed other ore-forming fluids to enter and fill the pores, resulting in further compaction of the pores. In contrast, the pressure coefficient of CS well #1 is 1.1–1.2, which effectively prevented other ore-forming fluids from entering and filling the pores. The findings show that the dynamic adjustment of the Dengying Formation palaeo-gas reservoir indirectly affects the preservation or failure of the reservoir. The occurrence and geometry of bitumen in the Dengying reservoir exhibit good consistency with the pressure changes in both boreholes. In particular, bitumen with an annular shape and contraction joints in reservoir pores is widespread in CS well #1, which is attributed to the continuous preservation of palaeo-gas fields. Conversely, bitumen with a broken particle shape is located among the epigenetic minerals widespread in MS well #1, which is attributed to failure and depletion of the palaeo-gas fields.

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