| Institute of Geomechanics, Chinese Academy of Geological Sciences | Host |
| Citation: |
XU Changgui, DU Xiaofeng, PANG Xiaojun, WANG Qiming, PAN Wenjing. 2022. The source-sink system and its control on large-area lithologic reservoirs of the lower Minghuazhen Formation in the southern Bohai Sea. Journal of Geomechanics, 28(5): 728-742. doi: 10.12090/j.issn.1006-6616.20222813
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The source-sink system and its control on large-area lithologic reservoirs of the lower Minghuazhen Formation in the southern Bohai Sea
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Abstract
In recent years, a large number of large-area sand bodies have been drilled in the Neogene in the southern Bohai Sea, and several 100-million-ton oilfields have been discovered, indicating that the lower member of the Minghuazhen Formation has enormous exploration potential. The source-sink elements of the development of such sand bodies are unclear, which seriously restricts the exploration of lithologic reservoirs in the lower member of the Minghuazhen Formation. Using paleontology, heavy minerals, seismic, drilling and other data, this paper explores the source-sink system and its control on large-area lithologic reservoirs in the lower member of the Minghuazhen Formation of the southern Bohai Sea. The results show that: The Yanshan-Liaoxi uplift, the Liaodong uplift, the Luxi uplift and the Jiaodong uplift mainly develop source-sink systems in four directions in the study area’s lower member of the Minghuazhen Formation. Next, the Luxi uplift and the Jiaodong uplift are relatively close. The Luxi uplift and the Liaodong uplift significantly impact the source-sink system in the study area’s lower part of the Minghuazhen Formation. In contrast, the Yanshan-Liaoxi uplift has a weaker impact on the source-sink system. Three sedimentary systems, including rivers, river-lake interactions and lakes, are mainly developed in the study area’s lower member of the Minghuazhen Formation. Among them, the sand bodies formed by river-lake interactions and lake shallow water deltas are larger. The study area’s lower member of the Minghuazhen Formation has favorable source-sink conditions for creating large-scale sand bodies. Among them, temperate-subtropical climate, sufficient rainfall, developed paleo-water system, felsic metamorphic rocks and magmatic parent rocks, and frequent expansion and shrinkage of lakes are beneficial to the development of large-area sand bodies. The connection of channel sand–sheet sand–channel sand leads to the development of large-scale lithologic traps in the study area’s lower member of the Minghuazhen Formation. Compared with channel sand alone, river-lake interactions and shallow water deltas have the potential to form large-area lithologic reservoirs. This understanding can help explore large Neogene oil and gas reservoirs in the Bohai Sea.
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References
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XU Changgui, DU Xiaofeng, PANG Xiaojun, WANG Qiming, PAN Wenjing. 2022. The source-sink system and its control on large-area lithologic reservoirs of the lower Minghuazhen Formation in the southern Bohai Sea. Journal of Geomechanics, 28(5): 728-742. doi: 10.12090/j.issn.1006-6616.20222813
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Figure 1.
Geotectonic position and stratigraphic comprehensive histogram of the Bohai Sea
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Figure 2.
Paleoclimate analysis of the southern Bohai Sea of Neogene
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Figure 3.
Source distribution and directions of the of main water systems in the southern Bohai Sea
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Figure 4.
Superimposition of paleo-geomorphology and paleo-water system in the lower Minghuazhen Formation in the southern Bohai Sea
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Figure 5.
Comparison of the relative percentages of heavy minerals in the lower member of the Minghuazhen Formation in the southern Bohai Sea
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Figure 6.
Seismic profile characteristics of the lower lower part of the lower member of the Minghuazhen Formation in the southern Bohai Sea (The SB02 layer is flattened. See Fig. 5 for the location of the seismic section)
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Figure 7.
Paleo-geomorphic characteristics of the lower member of the Minghuazhen Formation in different depositional stages in the southern Bohai Sea
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Figure 8.
Comparison of sedimentary characteristics of river system, river–lake interaction system and lake system
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Figure 9.
Distribution map of the sedimentary systems in the early and late sedimentation of the lower Minghuazhen Formation in the southern Bohai Sea
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Figure 10.
Model diagram of the source–sink system in the lower member of the Minghuazhen Formation in the southern Bohai Sea
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Figure 11.
Continuous distribution characteristics of the sand bodies and oil layers in the lower member of the Minghuazhen Formation of KL 6-1 structure in the southern Bohai Sea
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Figure 12.
Accumulation model and oil-bearing area distribution of the KL 6-1 structural lithologic reservoir in the lower member of the Minghuazhen Formation in the southern Bohai Sea