首页|期刊导航|地质科学|松辽盆地古龙凹陷青山口组页岩中的交错层理、大颗粒及叠瓦构造及其沉积动力学研究

松辽盆地古龙凹陷青山口组页岩中的交错层理、大颗粒及叠瓦构造及其沉积动力学研究OA

Study on shale cross-bedding,coarse grains,and imbricate structure with their sedimentary dynamics in the Qingshankou Formation of Gulong Sag,Songliao Basin

中文摘要英文摘要

泥页岩组构是重要的科学问题和勘探开发实际问题,而泥页岩组构在很大程度上取决于沉积方式、沉积环境及沉积动力.古龙凹陷青山口组页岩油勘探取得了重大突破,已探明油气资源量达151亿吨.过去,青山口组页岩一直被认为是深湖、半深湖静水低能的沉积产物.然而,近期在古龙凹陷青山口组页岩中发现的高能沉积构造及较粗大颗粒和砾屑,为重新认识青山口组页岩油的形成环境提供了新资料.本文通过岩心精细观察、薄片分析、高清视频显微镜及物理模拟实验研究了古龙凹陷青山口组页岩.结果表明,该套泥页岩中发育了大量代表较高能沉积环境的交错层理、大颗粒(直径最大12mm),还有厚度大于1cm左右的泥屑板片与砂岩板片及叠瓦构造.这些发现揭示古龙凹陷在青山口组沉积时并非低能静水环境,而是经常受到速度为0.15~0.35 m/s水流作用影响.为此,我们重新设计了一个模拟实验来研究颗粒的最小垂向悬浮速度(Vmf).实验选择了 9种粒度:0.125 mm、0.25 mm、0.50mm、1mm、2mm、10mm、20mm、30 mm 和 40 mm.为模拟 1.8 cm×6.8 cm 的硕大砂岩板片,使用40 mm砂岩圆球粒作为模拟上限.实验测得,直径12 mm的粉砂砾垂向悬浮幅度略大于0.447 m/s,直径40 mm的砂岩圆球粒的悬浮速度在1m/s左右,揭示了古龙凹陷青山口期风暴作用在湖底非常强烈.通过该实验还发现,利用前人公式计算的这9种粒度的最小悬浮速度远小于实验获得的速度.如果用前人公式计算的结果评估古龙凹陷青山口组的风暴动力,会严重低估其作用强度;因此,本次悬浮模拟实验大大推动了该区的风暴动力学研究.综上所述,古龙凹陷青山口组页岩经常受到以风暴为主的高能水流的作用,这种高能条件下发育的富含有机质的泥页岩,主要受益于当时大气严重缺氧形成的还原环境,而并非源于凹陷本身的深水、静水形成的还原环境.

The fabric of mudstone and shale is an important scientific issue and practical problem in the exploration and development.It is largely determined by the sedimentary mode,sedimentary environment and sedimentary dynamics.The exploration of shale oil in the Qingshankou Formation of Gulong Sag has achieved a major breakthrough,the oil and gas resources amount to 15.1 billion tons.Previously,the Qingshankou Formation shale was always regarded as the sedimentary product of a low-energy,quiet-water environment in deep-lake and semi-deep-lake settings.Recently,high-energy sedimentary structures,relatively large particles and gravel debris discovered in the Qingshankou Formation shale of Gulong Sag provide new evidence for reinterpreting its depositional environment.The shale of the Qingshankou Formation in Gulong Sag was studied through detailed core observation,thin section analysis,high-definition video microscopy and physical simulation experiments.The results reveal the development of numerous high-energy sedimentary structures,including cross-bedding,coarse grains(with a maximum diameter of 12 mm),as well as mudstone and sandstone chips over 1 cm thick,and imbricate structures.These findings reveal that the Gulong Sag was not a low-energy,quiet-water environment during the deposition of the Qingshankou Formation,but was frequently influenced by currents with velocities of 0.15~0.35 m/s.We conducted a simulation experiment to study the minimum vertical suspension velocity(Vmf)of particles.Nine particle sizes were selected:0.125 mm,0.25 mm,0.50 mm,1 mm,2 mm,10 mm,20 mm,30 mm and 40 mm.The experiment measured a critical suspension velocity slightly greater than 0.447 m/s for 12 mm silt-grained gravel and approximately 1 m/s for 40 mm sandstone spheres,attesting to intense storm-driven bottom currents in the Gulong Sag during the Qingshankou Period.Through this experiment,it was also found that the minimum suspension velocities calculated by the previous formulas for these nine particle sizes were much lower than the experimental values.If the results calculated using the previous formulas are used to assess the storm dynamics in the Qingshankou Formation of Gulong Sag,it would seriously underestimate the intensity of the storm's effect.Therefore,our suspension simulation experiment has greatly advanced the research on storm dynamics.The shale of the Qingshankou Formation of Gulong Sag was frequently influenced by high-energy water flows dominated by storms.The organic-rich shale developed under such high-energy conditions mainly benefits from the reducing environment formed by severe oxygen deficiency in the atmosphere at that time,rather than the deep-water,quiet-water reducing environment formed by the sag itself.

张金友;刘凤和;罗庆;钟建华;康德江;吴伟;王金伟;圣朋朋

多资源协同陆相页岩油绿色开采全国重点实验室 黑龙江大庆 163712||大庆油田有限责任公司勘探开发研究院 黑龙江大庆 163712多资源协同陆相页岩油绿色开采全国重点实验室 黑龙江大庆 163712||大庆油田有限责任公司 黑龙江大庆 163712多资源协同陆相页岩油绿色开采全国重点实验室 黑龙江大庆 163712||大庆油田有限责任公司勘探开发研究院 黑龙江大庆 163712东北大学秦皇岛分校资源与材料学院 河北秦皇岛 066004||海洋油气勘探国家工程研究中心 北京 100028||中国石油大学(华东)地球科学与技术学院 山东青岛 266580多资源协同陆相页岩油绿色开采全国重点实验室 黑龙江大庆 163712||大庆油田有限责任公司勘探开发研究院 黑龙江大庆 163712多资源协同陆相页岩油绿色开采全国重点实验室 黑龙江大庆 163712||大庆油田有限责任公司勘探开发研究院 黑龙江大庆 163712多资源协同陆相页岩油绿色开采全国重点实验室 黑龙江大庆 163712||大庆油田有限责任公司勘探开发研究院 黑龙江大庆 163712多资源协同陆相页岩油绿色开采全国重点实验室 黑龙江大庆 163712||大庆油田有限责任公司勘探开发研究院 黑龙江大庆 163712

天文与地球科学

页岩油交错层理大颗粒(≥12mm)风暴动力学最小悬浮速度(Vmf)青山口组古龙凹陷

Shale oilCross-beddingLarge particles(≥12 mm)Storm dynamicsMinimum suspending-flow velocity(Vmf)Qingshankou FormationGulong Sag

《地质科学》 2026 (2)

468-488,21

国家自然科学基金项目(编号:42072138,41572088)、中国石油天然气股份有限公司重大科技专项"大庆古龙页岩油勘探开发理论与关键技术研究"(编号:2021ZZ10)和黑龙江省"百千万"工程科技重大专项"松辽盆地北部古龙页岩油成藏条件及甜点分布规律研究"(编号:2020ZX05A01)资助

10.12017/dzkx.2026.032

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