Overpressure-Tectonic Activity Controlled Fluid Flow and Rapid Petroleum Accumulation in Bozhong Depression, Bohai Bay Basin
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摘要: 渤中坳陷是东营组沉积期及其之后渤海湾盆地沉降-沉积速率最高的地区, 亦是晚期断裂活动最强烈的地区.较高的沉降-沉积速率产生了重要的成藏物质效应: (1) 持续的较快速沉降-沉积使东营组发育较深湖-深湖相泥岩并成熟, 从而使渤中坳陷发育沙河街组和东营组2套有效源岩; (2) 较高的沉降-沉积速率引起的压实不均衡及伴生的源岩快速生烃引起较强的超压, 超压对有机质热演化的抑制作用使沙河街组源岩生、排烃滞后, 从而使沙河街组和东营组在晚期同时保持在较有利的生、排油阶段, 这是渤中坳陷油气资源丰富和油气晚期快速成藏的物质基础.较强的超压和强烈的断裂活动决定了超压-构造活动联控型流体流动, 进而决定了油气幕式快速成藏过程和油气分布: 油气主要富集于新近系, 新构造运动控制油气分布Abstract: Since the beginning of the deposition of Dongying Formation, the Bozhong depression has had the highest subsidence-sedimentation rates and the strongest late-stage (since 5.1 Ma) fault activity in the Bohai Bay basin. High subsidence-sedimentation rates have had very important "material" effects on petroleum accumulation. On one hand, both Dongying and Shahejie formations comprise effective source rocks in the Bozhong depression because of much thick overlying strata, whereas only Shahejie Formation is taken as effective source rocks in almost all other depressions in Bohai Bay basin. On the other hand, strong overpressure caused by compaction disequilibrium due to rapid subsidence and sedimentation retarded organic matter maturation especially hydrocarbon thermal destruction and delayed petroleum expulsion, which made both Shahejie and Dongying formations remain in a favorable conditions for petroleum generation and expulsion during late stage (since (5.1 Ma)). The "material effect" is a key for the rapid petroleum accumulation around Bozhong depression. The combination of strong overpressure and strong faulting during late stage controlled fluid flow as a result of episodic petroleum accumulation. Hence, such a process controls the distribution of petroleum occurring in Neogene strata.
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Key words:
- Bozhong depression /
- neotectonics /
- overpressure /
- episodic fluid flow /
- rapid petroleum accumulation
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图 1 渤海湾盆地主要构造单元沉降速率的比较
(据中海石油研究中心勘探研究部资料编绘)
Fig. 1. Comparison of the subsidence rates for different sub-units of the Bohai Bay basin
图 2 渤海湾盆地不同地区地层厚度和断裂发育特征的比较
(龚再升提供)
Fig. 2. Cross-section showing the difference in stratum thickness and fault features in different sub-units of the Bohai Bay basin
图 3 渤中坳陷CFD18-2E-1井有机质成熟度和粘土矿物演化剖面
Fig. 3. Organic matter maturation and clay mineral transformation profiles for Well CFD18-2E-1, Bozhong depression
图 4 渤中坳陷PL7-1-1井地层温度和压力剖面
Fig. 4. Temperature and pressure profiles for Well PL7-1-1, Bozhong depression
图 5 断裂带压力的积累、断裂开启和流体释放过程
Fig. 5. Schematic diagram showing the processes of the buildup overpressure, opening of the faults and release of overpressure fluid along a fault
图 6 随张应力增大/构造活动增强, 断裂门限开启压力(pTFO) 的变化
T.断裂带的抗张强度; σ3.构造松弛状态(应力完全由上覆地层负载产生的理想状态) 下的最小水平应力; ph.静水压力
Fig. 6. Variation of the threshold fluid pressure needed for fault opening with increasing tensile stress/strength of tectonic activities
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