Sedimentary sequence and prediction of favorable stratigraphic traps in the western slope zone of the southern-central Muglad Basin, Sudan

doi:10.13745/j.esf.sf.2020.5.13

Abstract

Abstract:

The Muglad Basin in Sudan is rich in oil and gas resources and currently is under intensive hydrocarbon exploration. The western slope of the southern-central part of the basin in the western slope zone of the Kaikang depression is one of the important exploration areas in the Muglad Basin. At present, the thickness of the remaining strata is about 5000 m as a result of severe denudation during the structural transformation period. Influenced by regional tectonic activities, the evolutionary development of the sedimentary reservoir in the study area is closely related to the tectonic evolution. In the study area, as exploration for tectonic traps entering the middle and late stages, finding new exploration fields and targets has become an urgent task, for which litho-stratigraphic trap exploration becomes an important approach. Currently, the major factor limiting oil and gas exploration is lacking a systematic understanding of the basic issues, such as the sequence stratigraphic structure of the western slope of the southern-central Muglad Basin. Here, we focused on the evolutionary characteristics of the sedimentary sequence of the western slope zone and their controlling factors through a comprehensive analysis of seismic, well logging and core data using the principle of sequence stratigraphy. We discussed the favorable source-reservoir-cap assemblage and predicted and evaluated the favorable stratigraphic traps in the study area. The main results and achievements are as follows: 1) The basin experienced three large rift movements and three post-rift thermal subsidence depression movements, which resulted in six secondary sequences. In this secondary sequence stratigraphic framework, the target formations, from Abu Gabra to Adok, were divided into thirteen third-order sequences. The filling and evolution of each sequence was controlled by regional tectonic background. 2) Stratigraphic development in the study area experienced three stages of rift-depression while the basin maintained its sedimentary characteristics under the control of structural background in each stage, with obvious difference in sedimentation controls. Based on the analyses of core, logging, earthquake, and paleocurrent in the western slope zone of the southern-central Muglad Basin, it is considered that the lake and braided river delta deposition system mainly developed during the rift period, whereas the braided river and delta mainly developed during the depression period. Due to multistage expansion and contraction of the lake basin, the sedimentary systems exhibited inherited and diverse spatiotemporal distributions. 3) According to the formation sequence of the Cretaceous-Paleogene source rocks, reservoirs and caprocks in the western slope and their spatial assemblage relationships, four sets of source-reservoir-cap assemblages could be identified in the study area featuring two main rock-forming types: the lower generation - upper reservoir type, and the self generation - self reservoir type. In the isochronous sequence stratigraphic framework of the study area, we identified two types of stratigraphic traps: stratigraphic erosion unconformity trap and stratigraphic overlap unconformity trap. The top interface of the sedimentary facies SQ5 in the western part of the study area is a regional erosive unconformity surface. It forms an erosive unconformity triangle with the underlying strata, creating a favorable stratigraphic erosive unconformity trap developing area. The sedimentary facies SQ4 in the northwestern part of the study area overlaps the unconformity surface, forming an overlap unconformity triangle zone—a favorable stratigraphic overlap unconformity trap developing area.

Key words: sedimentary sequence, stratigraphic trap, the western slope of Muglad Basin, Sudan

CLC Number:

RAN Huaijiang, FAN Leyuan, KONG Qingdong, XU Xiaojing. Sedimentary sequence and prediction of favorable stratigraphic traps in the western slope zone of the southern-central Muglad Basin, Sudan[J]. Earth Science Frontiers, 2021, 28(1): 131-140.

Figures/Tables 11

Fig.1 Tectonic units of the Muglad Basin and location of the study area

Fig.2 Comprehensive histogram of sedimentary sequence of the study area

Fig.3 Typical seismic profile of unconformity interface in the study area (T5-Tg)

Fig.4 Typical seismic profile of unconformity interface in the study area (T1-T4)

Fig.5 Typical logging response characteristics of sequence interface

Fig.6 Logging response characteristics of sequence interface and sedimentary facies division

Fig.7 Planar distribution of sedimentary facies SQ1, SQ6 and SQ11 in the study area

Fig.8 Depositional model of the rift-depression stage in the study area

Fig.9 Profile of source, reservoir and cap assemblies in the study area

Fig.10 The erode unconformable stratigraphic trap of the Nayil Formation (between T2 and T3)

Fig.11 The overlap unconformable stratigraphic trap of the Lower Bentiu Formation (between T51 and T6)

References 24

[1]	MORLEY C K, NELSON R A, PATTON T L, et al. Transfer zones in the East African Rift System and their relevance to hydrocarbon exploration in rifts[J]. AAPG Bulletin, 1990, 74(8):1234-1253.
[2]	SCHULL T J. Rift basins of interior Sudan: petroleum exploration and discovery[J]. AAPG Bulletin, 1988, 72(7):1128-1142.
[3]	GENIK G J. Regional framework, structural and petroleum aspects of rift basins in Niger, Chad and the Central African Republic[J]. Tectonophysics, 1992, 213(1/2):169-185. DOI URL
[4]	GENIK G J. Petroleum geology of Cretaceous-Tertiary rift basins in Niger, Chad, and Central African Republic[J]. AAPG Bulletin, 1993, 77(8):1405-1434.
[5]	MCHARGUE T R, HEIDRICK T L, LIVINGSTON J E. Tectonostratigraphic development of the Interior Sudan rifts, Central Africa[J]. Tectonophysics, 1992, 213(1/2):187-202. DOI URL
[6]	窦立荣, 潘校华, 田作基, 等. 苏丹裂谷盆地油气藏的形成与分布: 兼与中国东部裂谷盆地对比分析[J]. 石油勘探与开发, 2006, 33(3):255-261.
[7]	张亚敏, 陈发景. 穆格莱德盆地形成特点与勘探潜力[J]. 石油与天然气地质, 2002, 23(3):236-240.
[8]	李娟, 陈红汉, 张光亚, 等. Muglad盆地凯康坳陷生长断层活动定量分析及对油气成藏的控制[J]. 地学前缘, 2018, 25(2):51-61.
[9]	童晓光, 窦立荣, 田作基, 等. 苏丹穆格莱特盆地的地质模式和成藏模式[J]. 石油学报, 2004, 25(1):19-24.
[10]	MAKEEN Y M, ABDULLAH W H, HAKIMI M H, et al. Source rock characteristics of the Lower Cretaceous Abu Gabra Formation in the Muglad Basin, Sudan, and its relevance to oil generation studies[J]. Marine and Petroleum Geology, 2015, 59:505-516. DOI URL
[11]	DOU L R, CHENG D S, LI Z, et al. Petroleum geology of the Fula Sub-basin[J]. Journal of Petroleum Geology, 2013, 36(1):43-60. DOI URL
[12]	李威, 窦立荣, 张光亚, 等. 苏丹Muglad盆地Fula坳陷油气地球化学特征与成藏意义[J]. 地学前缘, 2018, 25(2):121-129.
[13]	张亚敏, 漆家福. 穆格莱德盆地构造地质特征与油气富集[J]. 石油与天然气地质, 2007, 28(5):669-674.
[14]	王国林, 汪望泉, 郑永林, 等. 苏丹穆格莱德盆地油气地质新进展与勘探新领域[J]. 地学前缘, 2018, 25(2):33-41.
[15]	贾义蓉, 方乐华, 李碧宁, 等. 中非Muglad盆地1/2/4区块白垩系构造特征与油气分布[J]. 石油物探, 2012, 51(3):296-303.
[16]	CATUNEANU O, ABREU V, BHATTACHARYA J P, et al. Towards the standardization of sequence stratigraphy[J]. Earth-Science Reviews, 2009, 92:1-33. DOI URL
[17]	朱筱敏. 层序地层学[M]. 东营: 中国石油大学出版社, 2006.
[18]	姜在兴. 层序地层学研究进展: 国际层序地层学研讨会综述[J]. 地学前缘, 2012, 19(1):1-9.
[19]	李美俊, 李思田, 杨龙, 等. 层序地层地球化学及其在油气勘探中的作用[J]. 地学前缘, 2005, 12(3):219-226.
[20]	薛良清, 樊太亮, 许大丰, 等. 苏丹Muglad盆地东北部AG组层序地层研究与勘探目标评价[J]. 石油与天然气地质, 2004, 25(5):506-512.
[21]	冉怀江, 范乐元, 胡圣利, 等. 苏丹Muglad盆地凯康凹陷西斜坡早白垩世沉积层序及其控制因素研究[J]. 现代地质, 2014, 28(4):799-805.
[22]	范乐元, 温银宇, 金博, 等. 穆格莱德盆地凯康坳陷西斜坡地层剥蚀与埋藏史研究[J]. 西安石油大学学报(自然科学版), 2013, 28(3):21-27, 33.
	杨俊生, 朱筱敏. 苏丹Muglad盆地Fula坳陷白垩系Abu Gabra组层序地层及沉积体系[J]. 沉积学报, 2008, 26(6):994-100.
[24]	陶文芳, 朱筱敏, 范乐元, 等. 苏丹穆格莱德盆地X区西斜坡AG组—Tendi组沉积体系分析[J]. 岩性油气藏, 2014, 26(3):51-58.