松辽盆地北部青山口组重力流特征研究及其地质意义   总被引：1，自引：1，他引：0  

杜锦霞 《沉积学报》2015,33(2):385-393

为在陆相湖盆寻找有利勘探目标,在岩芯观察和沉积、构造分析的基础上,对岩芯观察资料、三维地震资料、钻井资料和测井曲线资料等进行了较为详细的研究。研究表明,松辽盆地北部青山口组发育广泛的湖相泥岩沉积,沉积相主要为三角洲平原、三角洲内前缘、三角洲外前缘、深湖-半深湖和滨湖。湖区发育大规模重力流沉积,该区发现的重力流沉积主要有滑动岩型、滑塌岩型、碎屑流型、浊积岩型等类型;重力流岩石学特征表明青山口组二段下部的重力流沉积,主要为滑动岩型和滑塌型,岩性主要以粉砂岩,泥质粉砂岩,粉砂质泥岩薄互层为特征,局部含油或有油迹;而青山口组一段顶部的重力流沉积,主要为碎屑流型和浊流型,岩性上以粗砂岩、粉砂岩、粉砂质泥岩、泥岩的薄互层为主。初步探讨了重力流的发育和控制机制,分析表明青山口组重力流沉积是湖区的有利储层区域,英台大安地区为最有利储层。该研究对深入了解湖相储层特征起指导作用。重力流沉积勘探在松辽盆地还处于探索阶段,其研究为在大型陆相湖盆中寻找新的有利勘探目标奠定坚实基础。在陆相湖盆中研究深水重力流沉积,对沉积学研究具有推动作用。  相似文献   

鄂尔多斯晚三叠世湖盆异重流沉积新发现   总被引：15，自引：4，他引：11  

杨仁超  金之钧  孙冬胜  樊爱萍 《沉积学报》2015,33(1):10-20

水下重力流沉积作为重要的油气储层,已成为当前学术研究和油气工业共同关注的焦点.在鄂尔多斯盆地南部延长组长7~长6油层组深湖相沉积中,发现一种不同于砂质碎屑流沉积和滑塌浊积岩的重力流成因砂岩.其沉积特征为一系列向上变粗的单元(逆粒序层)和向上变细的单元(正粒序层)成对出现;每一个粒序层组合内部的泥质含量变化(高-低-高)与粒度变化一致;上部正粒序层与下部逆粒序层之间可见层内微侵蚀界面;砂岩与灰黑色纯泥岩、深灰色粉砂质泥岩互层;粉砂质泥岩层内也表现出类似的粒度变化特征.通过岩芯观察和薄片鉴定,认为该岩石组合形成于晚三叠世深湖背景下的异重流(hyperpycnal flow)沉积.其沉积产物--hyperpycnite(异重岩?)以发育逆粒序和层内微侵蚀面而区别于其它浊积岩,逆粒序代表洪水增强期的产物,上部的正粒序层为洪水衰退期的沉积,逆粒序-正粒序的成对出现代表一次洪水异重流事件沉积旋回;层内微侵蚀面是洪峰期流速足以对同期先沉淀的逆粒序沉积层侵蚀造成的.鄂尔多斯盆地延长组异重岩的发现,不仅为探索陆相湖盆环境下的异重流沉积提供了一个范例,而且对于深水砂体成因研究、储层预测和油气勘探具有理论和现实意义.  相似文献   

四川盆地东部三叠系嘉陵江组成盐期浓缩海水古温度及其意义   总被引：2，自引：0，他引：2  

汪明泉  赵艳军  刘成林  丁婷 《岩石学报》2015,31(9):2745-2750

四川盆地东部嘉陵江组四段石盐岩中发育大量原生的单一液相包裹体,为揭示石盐结晶时古海水的温度,恢复早三叠世古气候提供了有利条件。本文在蒸发岩岩相学研究的基础上,对流体包裹体均一温度进行了测试。测温结果表明,石盐结晶时卤水的温度在17.7~63.5℃之间,与该地区碳酸盐岩氧同位素数据所反映的温度特征基本一致,说明早三叠世时海水具有较高的温度。这有利于古海水的强烈蒸发浓缩,为成钾奠定了良好的气候条件。  相似文献   

塔北西部一间房组碳酸盐岩礁滩体同生期暴露溶蚀作用模式          下载免费PDF全文

赵学钦  杨海军马 青周成刚  孙崇浩蔡 泉 孙仕勇 《中国地质》2015,(6):1811-1811

在详细的钻井资料和岩心的宏观及微观特征研究的基础上,通过对塔北隆起西部奥陶系中统一间房组礁滩体沉积相特征及展布规律的分析,结合礁滩体储层同生期溶蚀作用特征研究,按照古沉积地貌单元结合岩相的方法建立了一间房组礁滩体同生期溶蚀作用模式。研究认为一间房组开阔台地相包括台内滩、滩间海和台内点礁3个亚相,沉积相平面分布稳定;一间房组的同生期暴露溶蚀作用明显,普遍反映出滩体的间歇性暴露的特征:生物钻孔和溶蚀孔洞内充填礁滩体暴露形成的古土壤泥;发育潮间带的化石碎片堆积和软体生物活动遗迹;岩心观察和成像测井可以识别出渗流-潜流带溶蚀作用旋回。按照礁滩相沉积地貌结合岩相的模式,将一间房组开阔台地的浅滩和点礁沉积划分出潮上长期暴露滩、潮间间歇暴露滩、潮下高能滩、瓶筐石障积礁、潮汐水道等地貌单元。  相似文献   

西藏羌塘盆地东部中侏罗统混合沉积层序地层学研究   总被引：4，自引：2，他引：2       下载免费PDF全文

杨 莉马伯永  李尚林王根厚 《中国地质》2015,(4):1037-1045

西藏羌塘盆地东部中侏罗统广泛发育陆源碎屑与碳酸盐的混合沉积。综合前人研究成果,结合区域地质资料和室内样品分析,本文对陆源碎屑岩、碳酸盐岩、混积岩及混积层系,混合层序地层进行了详细研究。研究结果表明,混合沉积在微观上表现为陆源碎屑与碳酸盐沉积物组分的混积岩,宏观上则表现为陆源碎屑岩、碳酸盐岩、混积岩相互叠加的混积层系,发育滨岸、碳酸盐岩缓坡、潮坪-溻湖、三角洲等沉积体系。运用层序地层学原理将中侏罗统划分为SQ1-SQ4四个三级层序,提高了研究区层序地层划分精度;探讨了混合沉积与层序地层的对应关系。总体上看,以陆源碎屑沉积为主的沉积背景下,混合沉积主要发育在海侵体系域的早期和高位体系域的晚期。以碳酸盐沉积为主的沉积背景下,混合沉积主要发育在海侵体系域的早期和高位体系域的晚期。  相似文献   

Hydrocarbon Inclusion Characteristics in the Cambrian-Ordovician Carbonates of the TS2 Well: Implication for Deep Hydrocarbon Exploration in the Tahe Oilfield,Tarim Basin,Northwest China     

LI Chunquan  CHEN Honghan 《《地质学报》英文版》2015,89(3):852-860

Going deep has been the strategy for the sustainable development of the Tahe Oilfield.Following the TS1 well in block 1,which revealed excellent combinations of hydrocarbon generation,migration and accumulation in the deeper parts of the Tarim Basin,the TS2 well was drilled to learn more about the prospectivity in the deeper parts of the main blocks of the Tahe Oilfield.Seventeen core samples were collected to perform fluid inclusion studies,including petrography,fluorescence microspectrometry,and microthermometry.The results show that the deeper parts of the Tahe Oilfield have a good hydrocarbon potential.The Cambrian source rocks can supply sufficient oil for not only the Cambrian reservoirs,but also for the Lower Ordovician reservoirs.The CambrianOrdovician carbonates reservoirs experienced at least three oil charging events and one late gas charging event.Oil accumulations formed in the early stage of basin evolution were likely destroyed in the late stage with deep burial,tectonic movements,or invasion of hydrothermal fluids.Therefore,the deep hydrocarbon exploration of the Tahe Oilfield,even the whole Tarim Basin,should focus on gas accumulations,although oil accumulations,especially in Cambrian reservoirs,cannot be neglected.  相似文献   

Exhumation History of the Xining Basin Since the Mesozoic and Its Tectonic Significance     

WANG Yannan  ZHANG Jin  QI Wenhu  GUO Shan 《《地质学报》英文版》2015,89(1):145-162

The Xining Basin is located in the northeastern Qinghai–Tibetan Plateau, and its continuous Cenozoic strata record the entire uplift and outgrowth history of the Tibetan Plateau during the Cenozoic. The newly obtained apatite fission track data presented here shows that the Xining Basin and two marginal mountain ranges have experienced multiphase rapid cooling since the Jurassic, as follows. In the Middle–Late Jurassic, the rapid exhumation of the former Xining Basin resulted from collision between the Qiangtang Block and the Tarim Block. During the Early–Late Cretaceous, the former Xining Basin underwent a tectonic event due to marginal compression, causing the angular unconformity between the Upper and Lower Cretaceous. In the Late Cretaceous to the Early Cenozoic, collision between the Qiangtang Block and the Lhasa Block may have resulted in the rapid exhumation of the Xining Basin and the Lajishan to the south. In the Early Cenozoic(ca. 50–30 Ma), collision between the Indian and Eurasia plates affected the region that corresponds to the present northeastern Qinghai–Tibetan Plateau. During this period, the central Qilian Block rotated clockwise by approximately 24° to form a wedge-shaped basin(i.e., the Xining Basin) opening to the west. During ca. 17–8 Ma, the entire northeastern Qinghai–Tibetan Plateau underwent dramatic deformation, and the Lajishan uplifted rapidly owing to the northward compression of the Guide Basin from the south. A marked change in subsidence occurred in the Xining Basin during this period, when the basin was tectonically inverted.  相似文献   

Geochemical Characteristics of Volcanic Rocks from ODP Site 794, Yamato Basin: Implications for Deep Mantle Processes of the Japan Sea   总被引：1，自引：0，他引：1  

CHEN Shuangshuang  LIU Jiaqi  GUO Zhengfu  CHEN Shengsheng  SUN Chunqing 《《地质学报》英文版》2015,89(4):1189-1212

Deep mantle processes and the dynamic mechanism of magmatism in the Japan Sea Basin are important processes that have not been studied in detail. In this paper, systematic evaluation of basalt samples from the ocean drilling program Site 794 in the Japan Sea was performed, which included petrography, whole-rock major- and trace-element analysis, Sr-Nd-Pb isotopic composition, and electron microprobe analysis of plagioclase and clinopyroxene. These basalts belong to the tholeiitic series with porphyritic texture and massive Ca-rich plagioclase, clinopyroxene, and minor olivine phenocrysts. The basalts are characterized as flat rare earth elements and high-field-strength elements with remarkably low ratios of(La/Yb)N(0.75–2.51), significant positive anomalies of Ba, Sr, and Rb and no Eu anomaly(δEu = 0.99–1.36). The samples showed relatively high 87Sr/86Sr(0.70425–0.70522), 207Pb/204Pb(15.511–15.610), and 208Pb/204Pb(38.064–38.557) values and a low 143Nd/144 Nd ratio(0.51271–0.51295). The basalts from Site 794 can be divided into upper, middle, and lower volcanic rocks(UVR, MVR, and LVR) on the basis of their stratigraphic level. The MVR was geochemically derived from the depleted mantle, whereas the UVR and LVR originated from a nondepleted and relatively enriched mantle source with contributions from subducted Pacific plate fluid and sediments. Use of geothermobarometers indicates that the crystallization pressure for the UVR and LVR(6.25–11.19 kbar) was significantly higher than that of the MVR(3.48–5.84 kbar). The UVR and LVR may have been derived from the low-degree(5%–10%) partial melting of spinel lherzolite, while the MVR originated from a shallower mantle source with a high degree(10%–20%) of partial melting. In addition, the geochemical characteristics of the samples are consistent with a younger age(13–17 Ma) and the depleted composition of the MVR and an older age(17–23 Ma) and slightly enriched composition of the UVR and LVR. Therefore, temporal changes in the mantle source from old and enriched to young and depleted and subsequently to old and nondepleted may have been associated with progressive lithospheric extension and thinning, as well as at least two episodes of diverse asthenospheric upwelling and pull-apart tectonic motion in the Yamato Basin.  相似文献   

Structural Evolution and Hydrocarbon Potential of the Upper Paleozoic Northern Ordos Basin, North China     

YANG Minghui  LI Liang  ZHOU Jin  JIA Huichong  SUN Xiao  GONG Ting  DING Chao 《《地质学报》英文版》2015,89(5):1636-1648

The hydrocarbon potential of the Hangjinqi area in the northern Ordos Basin is not well known, compared to the other areas of the basin, despite its substantial petroleum system.Restoration of a depth-converted seismic profile across the Hangjinqi Fault Zone(HFZ) in the eastern Hangjinqi area shows one compression that created anticlinal structures in the Late Triassic, and two extensions in ~Middle Jurassic and Late Early Cretaceous, which were interrupted by inversions in the Late Jurassic–Early Early Cretaceous and Late Cretaceous, respectively.Hydrocarbon generation at the well locations in the Central Ordos Basin(COB) began in the Late Triassic.Basin modeling of Well Zhao-4 suggests that hydrocarbon generation from the Late Carboniferous–Early Permian coal measures of the northern Shanbei Slope peaked in the Early Cretaceous, predating the inversion in the Late Cretaceous.Most source rocks in the Shanbei Slope passed the main gas-migration phase except for the Hangjinqi area source rocks(Well Jin-48).Hydrocarbons generated from the COB are likely to have migrated northward toward the anticlinal structures and traps along the HFZ because the basin-fill strata are dipping south.Faulting that continued during the extensional phase(Late Early Cretaceous) of the Hangjinqi area probably acted as conduits for the migration of hydrocarbons.Thus, the anticlinal structures and associated traps to the north of the HFZ might have trapped hydrocarbons that were charged from the Late Carboniferous–Early Permian coal measures in the COB since the Middle Jurassic.  相似文献   

Improved Geometric Model of Extensional Fault–bend Folding     

ZHENG Xiaoli  HE Guangyu  HU Senqing  YAO Zewei  WANG Hui  LIN Lu 《《地质学报》英文版》2015,89(6):1847-1857

Extensional fault–bend folds, also called rollovers, are one of the most common structures in extensional settings. Numerous studies have shown that oblique simple shear is the most appropriate mechanism for quantitative modeling of geometric relations between normal faults and the strata in their hanging walls. However, the oblique simple shear has a rather serious issue derived from the shear direction, particularly above convex bends. We use geometric and experimental methods to study the deformation of extensional fault–bend folds on convex bends. The results indicate that whether the fault bends are concave or convex, the shear direction of the hanging wall dips toward the main fault. On this basis, we improve the previous geometric model by changing the shear direction above the convex bends. To illustrate basin history, our model highlights the importance of the outer limit of folding instead of the growth axial. Moreover, we propose a new expression for the expansion index that is applicable to the condition of no deposition on the footwall. This model is validated by modeling a natural structure of the East China Sea Basin.  相似文献