Oil filling history of the Bashituo Oilfield in the Markit Slope,SW Tarim Basin,China

The Markit Slope is an important area for the petroleum exploration in the Tarim Basin. Elucidation of the oil filling history of discovered oilfields has great significance for recognizing the accumulation processes of the whole region. Using molecular geochemistry, fluid inclusion techniques and basin modeling, we studied the oil filling process of the Bashituo Oilfield that is located in the west of the Markit Slope. The molecular migration indexes, such as the methyldibenzothiophene ratio （4-/1-MDBT）, trimethylnaphthalene ratio （TMNr） and pyrrolic nitrogen compounds content, decrease from west to east, indicating that the charging direction and migration pathways are from west to east. Lithological analysis and homogenization temperatures of saline fluid inclusions accompanied with oil fluid inclusions suggest that two charging periods occurred in the Devonian oil reservoir. Combining the burial history and heating history of well BT4, Basinmod 1D software modeling shows the two oil filling periods are from 290 Ma to 285 Ma and from l0 Ma to 4 Ma, respectively, and later oil filling dominates. This study may be helpful to understand the accumulation process and provide useful references for oil and gas exploration in the Markit Slope.

Sedimentation Rate Rhythms:Evidence from Filling of the Tarim Basin,Northwest China

Variations of sedimentation rate within a basin over geologic time are a time series that can be filtered into several cyclic wave curves. Based on back-stripping and the empirical mode decomposition method, the cores from 14 wells in the Tarim Basin were selected to do filtering analysis. Four cycles or quasi-cycles （33 Ma, 64.4 Ma, 103.6 Ma, and 224 Ma） were obtained. Among these, the 33 Ma period, which was related to the internal earth activity, an external force, or a combination of the two, was the most obvious. The 64.4 Ma period corresponded to the solar system crossing the galaxy plane or the periodic melting of inner-earth material. The 103.6 Ma period was related with plate collisional tectonism around the Tarim Plate. The 224 Ma period was related to one galaxy year and may also be related to the aesthenospherical convection cycle.

Incised valley filling deposits:an important pathway system for long-distance hydrocarbon migration—a case study of the Fulaerji Oilfield in the Songliao Basin

In this paper, incised valley filling deposits, which formed an important pathway system for long-distance hydrocarbon migration, are discussed in detail based on core and logging data. The sequence SQy23 of the Cretaceous Yaojia Formation is the main hydrocarbon-bearing layer in the Fulaerji Oilfield. The hydrocarbon source of the oilfield is the Qijia-Gulong Sag which is about 80 km away from the Fulaerji Oilfield. The transport layer of long-distance hydrocarbon migration is the overlapped sandstone complex which fills the incised valley. The incised valley developed during the depositional period from the late Qingshankou Formation to the early Yaojia Formation of Cretaceous （SQqna-SQy0 was about 70 km long and 20 km wide, and extended in the NW-SE direction. The overlapped filling of the incised valley mainly occurred in the expanding system tract of the third-order sequence SQy23 （ESTy23）. Towards the basin, incised valley filling deposits overlapped on the delta developed in the early period, and towards the basin margin, incised valley filling deposits were covered by the shore-shallow lacustrine sandy beach bar developed in the maximum flooding period. All of the delta, the incised valley filling and the shore-shallow sandy beach bar are sandstone-rich, and have high porosity and permeability, and can form an effective hydrocarbon migration and accumulation system. Deltaic sand bodies collected and pumped hydrocarbon from the active source, incised valley filling depositional system completed the long-distance hydrocarbon migration, and lithological traps of shore-shallow lacustrine sandy beach bar accumulated hydrocarbon. The incised valley filling sequences are multi-cycle： an integrated shortterm filling cycle was developed on the erosion surface, and the sequences upward were mud-gravel stone, medium-fine sandstone containing terrigenous gravels and muddy pebbles with cross bedding, silty mudstone with ripple bedding, and mudstone. The incised valley filling deposits are characterized by a strong heterogeneity and the main hydrocarbon migration pathway is the medium-fine sandstone interval.

Sedimentary system characteristics and depositional filling model of Upper Permian——Lower Triassic in South Yellow Sea Basin

In the South Yellow Sea Basin,Mesozoic–Paleozoic marine strata are generally well developed with large thickness,and no substantial breakthroughs have been made in hydrocarbon exploration.Through research,it is believed that the Upper Permian–Lower Triassic can be regarded as a long-term base-level cycle.Based on drilling data,characteristics of the lithology–electric property combination cyclicity,and the special lithology,the long-term base-level cycle was divided into five medium-term base-level cycles(MC1–MC5).On this basis,the Permian–Triassic sedimentary systems and their filling model were analyzed in accordance with the change of base-level cycle and transition of sedimentary environment,as well as characteristics of the drilling sedimentary facies and seismic facies.The results show that there were six sedimentary systems(fluvial,delta,tidal flat,open platform,restricted platform,and continental shelf)developed in the Upper Permian–Lower Triassic,the sedimentary systems were distributed such that the water was deep in the northwest and shallow in the southeast,and there were two base-level cycle filling models(a relatively stable tidal flat facies and a rapidly transgressive continental shelf facies to stable platform facies)developed in the Upper Permian–Lower Triassic.These models can provide a basis for evaluation of the Mesozoic–Paleozoic hydrocarbon geology in the South Yellow Sea Basin.

The Sequence Architecture of Volcanic Basin Fillings-An Example From Xujiaweizi Faulted Depression In Songliao Basin

The basin filling geometric pattern of volcanic eruptive rocks depends on both of the eruptive locations in a basin and structural styles of fault terraces. It is divided into three types by eruptive locations and occurrences of eruptive rocks, including the pattern of eruption along fault and occurrence (PEAFO), the pattern of eruption on footwall of a fault and occurrence (PEOFO) and the pattern of eruption on hangingwall of fault and occurrence (PEOHO) in Xujiaweizi fault depression of Songliao basin, Northeast of China. Those basin filling patterns of volcanic eruptive rocks are of specific geometric characteristics controlling or affecting sedimentation, geometry of sedimentary body and sequence architecture during a sequence evolution. The study shows that the volcanic rocks developed at different stages of lowstand, transgressive and highstand can give different controls or affects on the sequence architecture.

Sedimentary filling characteristics and controlling factors of lacustrine microbial carbonates sequence in the Santos Basin,Brazil

Based on comprehensive analysis of seismic,logging,core,thin section data,and stable isotopic compositions of carbon and oxygen,the sedimentary filling characteristics of the Lower Cretaceous Barra Velha Formation sequence in H oil field,Santos Basin,are studied,and the high-frequency sequence stratigraphic framework is established,and the spatial distribution of reef-shoal bodies are predicted and the controlling factors are discussed.During the depositional period of the Barra Velha Formation,the study area is a slope-isolated platform-slope sedimentary pattern from southwest to northeast and the change of climate background from rift to depression periods has resulted in the variation of sedimentary characteristics from the lower third-order sequence SQ1(BVE 300 Member)of low-energy deep water to the upper third-order sequence SQ2(BVE 200 and 100 members)of high-energy shallow water in the Barra Velha Formation.The activities of extensional faults and strike-slip faults in rift period and the sedimentary differentiation from platform margin to intra-platform in depression period made the sedimentary paleogeomorphology in these two periods show features of“three ridges and two depressions”.The reef-shoal bodies mainly developed in the SQ2-LHST period,with vertical development positions restricted by the periodic oscillation of the lake level,and developed on the top of each high-frequency sequence stratigraphic unit in SQ2-LHST in the platform.The strike-slip fault activity controlled the distribution of the reef-shoal bodies on the plane by changing the sedimentary paleogeomorphology.The positive flower-shaped strike-slip faults made the formation of local highlands at the margins of and inside the shallow water platforms and which became high-energy sedimentary zones,creating conditions for the development of reef-shoal bodies.

THE TECTONIC PROCESS AND THE FILLING OF TERRESTRIAL BASIN

The relation and unity of the tectonic process and sedimentation is being paid a good deal of attention. It is very obvious that the sedimentary process of the terrestrial basin is controlled by tectogenesis. The sedimentary evolution of the basin is the reflection of the tectonic evolution . The sedimentary process of the terrestrial basin has unique characteristics.(1) The scope of the terrestrial basin is mainly controlled by the fault zones.(2) The regional tectonic cycle obviously controls the sedimentary sequence boundary of the terrestrial basin. The periodicity of tectogenesis causes the periodic change of the sedimentary sequence.(3) The sedimentary model of the terrestrial basin is obviously controlled by the tectonic framework.(4) There are many surprise sedimentary events in sedimentary formation of the terrestrial basin.(5) Owing to the influence of the tectonization, the deformation frequently occurs in the sedimentary deposit.(6) Because the sediments of the terrestrial basin have the short\|distance transport, the sediments have the low mature index.(7) There are more sedimentary centres, more matter\|sources, narrow sedimentary facies\|zone and the quick facies change in the terrestrial basin.According to the background of the tectonic dynamics, the terrestrial basin can be divided into the extension basin, the compression basin and the shear basin. The three basins differ greatly in the sedimentary characteristics. The extension basin is usually directed at rift basin. The border of the extension basin is mainly the normal fault or growth fault. The plane shape of the extension is zone\|shape. The sedimentary deposit of the extension basin has not strong deformation. The thickness of the sediment on the downthrow wall is greater than that the sediment on the upcast wall. The periodic change of the tectogenesis causes the enlarging or the contract of the extension basin.

STRATIGRAPHIC AND DEPOSITIONAL FILLING MODEL OF NORTH TARIM FORELAND BASIN SYSTEM

A stratigraphic and depositional filling modal of Triassic—Jurassic North Tarim foreland basin system is erected, through synthetic analysis of geological setting, depositional provenance, sequence stratigraphy, and quantitative tectonic stratigraphy. The result suggests that the major factors controlling formation and evolution of the system are oblique collision and convergence of different plates, and favorite hydrocarbon plays is predicted.The geological setting analysis emphasizes the historical succession of the foreland basin system formation and evolution. The tectonic setting analysis sketchy outlines formation of the system and tectonic setting of its successive evolution. The sedimentary geology analysis reveals the uplift and subsidence of the basin basement a seesaw style movement.

Base level changes based on Basin Filling Modelling:a case study from the Paleocene Lishui Sag,East China Sea Basin

Estimation of base level changes in geological records is an important topic for petroleum geologists.Taking the Paleocene Upper Lingfeng Member of Lishui Sag as an example,this paper conducted a base level reconstruction based on Basin Filling Modelling(BFM).The reconstruction was processed on the ground of a previously interpreted seismic stratigraphic framework with several assumptions and simplification.The BFM is implemented with a nonlinear diffusion equation solver written in R coding that excels in shallow marine stratigraphic simulation.The modeled results fit the original stratigraphy very well.The BFM is a powerful tool for reconstructing the base level,and is an effective way to check the reasonableness of previous interpretations.Although simulation solutions may not be unique,the BFM still provides us a chance to gain some insights into the mechanism and dynamic details of the stratigraphy of sedimentary basins.

Study on Basin-Filling and Reservoir Sedimentology of Zhu Ⅲ Depression of Pearl River Mouth Basin,South China Sea

Through basin-filling analysis, one coarsening-upward and two fining-upward sequences have been identified in Zhu Ⅲ depression. In accondance with the general model proposed by Ravnas and Steel (1998), the basin-filling has two large cycles—rift (sediment-balanced and -overfilled) and postrift (sedimentunderfilled and starved). During the rifting process, the rifted lake developed through three stages: early, climax and late. The sedimentary characteristics of reservoir rocks show that barrier bar, lagoon and tidal channel facies well developed in Zhuhai Formation; offshore, tidal and barrier bar well developed in Zhujiang Formation. Neighborly, Shenhu, Wenchang and Enping formations deposited in rifted lakes during Paleogene time; Zhujiang Formation deposited in bay, lagoon and shoreface in late Paleogene. Zhujiang and other formations deposited in offshore and open shallow sea to shelf.

Difference in full-filled time and its controlling factors in the Central Canyon of the Qiongdongnan Basin

Based on the interpretation of high resolution 2D/3D seismic data, sedimentary filling characteristics and full- filled time of the Central Canyon in different segments in the Qiongdongnan Basin of northwestern South China Sea have been studied. The research results indicate that the initial formation age of the Central Canyon is traced back to 11.6 Ma （T40）, at which the canyon began to develop due to the scouring of turbidity currents from west to east. During the period of 11.6-8.2 Ma （T40-T31）, strong downcutting by gravity flow occurred, which led to the formation of the canyon. The canyon fillings began to form since 8.2 Ma （T31） and were dominated by turbidite deposits, which constituted of lateral migration and vertical superposition of turbidity channels during the time of 8.2-5.5 Ma. The interbeds of turbidity currents deposits and mass transport deposits （MTDs） were developed in the period of 5.5-3.8 Ma （T30-T28）. After then, the canyon fillings were primarily made up of large scale MTDs, interrupted by small scale turbidity channels and thin pelagic mudstones. The Central Canyon can be divided into three types according to the main controlling factors, geomorphology-controlled, fault-controlled and intrusion- modified canyons. Among them, the geomorphology-controlled canyon is developed at the Ledong, Lingshui, Songnan and western Baodao Depressions, situated in a confined basin center between the northern slope and the South Uplift Belt along the Central Depression Belt. The fault-controlled canyon is developed mainly along the deep-seated faults in the Changchang Depression and eastern Baodao Depression. Intrusion-modified canyon is only occurred in the Songnan Low Uplift, which is still mainly controlled by geomorphology, the intrusion just modified seabed morphology. The full-filled time of the Central Canyon differs from west to east, displaying a tendency of being successively late eastward. The geomorphology-controlled canyon was completely filled before 3.8 Ma （T28）, but that in intrusion-modified canyon was delayed to 2.4 Ma （T27） because of the uplifted southern canyon wall. To the Changchang Depression, the complete filling time was successively late eastward, and the canyon in eastern Changchang Depression is still not fully filled up to today. Difference in full-filled time in the Central Canyon is mainly governed by multiple sediment supplies and regional tectonic activities. Due to sufficient supply of turbidity currents and MTDs from west and north respectively, western segment of the Central Canyon is entirely filled up earlier. Owing to slower sediment supply rate, together with differential subsidence by deep-seated faults, the full-filled time of the canyon is put off eastwards gradually.

A Filled Function with Adjustable Parameters for Unconstrained Global Optimization

A filled function with adjustable parameters is suggested in this paper for finding a global minimum point of a general class of nonlinear programming problems with a bounded and closed domain. This function has two adjustable parameters. We will discuss the properties of the proposed filled function. Conditions on this function and on the values of parameters are given so that the constructed function has the desired properties of traditional filled function.

FILLED FUNCTIONS FOR UNCONSTRAINED GLOBAL OPTIMIZATION

The paper is concerned with the filled functions for global optimization of a continuous function of several variables.More general forms of filled functions are presented for smooth and nonsmooth optimizations.These functions have either two adjustable parameters or one adjustable parameter.Conditions on functions and on the values of parameters are given so that the constructed functions are desired filled functions.

内蒙古大青山侏罗纪沉积盆地充填和构造古地貌重建

石拐盆地是阴山地区保存最完整的侏罗纪盆地,其沉积充填过程和碎屑物质组成为正确认识大青山侏罗纪构造地貌演化提供了重要约束。石拐盆地形成于伸展断陷环境,依次充填了下侏罗统五当沟组和中侏罗统召沟组。断陷初期,南部地貌陡峭,控制发育了冲积扇沉积体系,碎屑组分记录了近源高级变质地体的剥露过程;晚期以坳陷为主,在召沟组末期形成最大湖泛面,碎屑组分中沉积岩岩屑和砾石明显增多,指示构造平静阶段的地貌夷平。至中—晚侏罗世,大青山地区构造属性发生反转,断陷盆地南部开始卷入挤压变形,形成大青山褶皱—逆冲系统雏形。然而,这些新生的挤压构造似乎未能引起地表地形的剧烈起伏,它们主要表现为隐伏状态。相反,该时期北部地貌抬升最为显著,不仅体现在中侏罗统长汉沟组和上侏罗统大青山组边缘相沉积均分布在盆地北部,更体现在阴山地体中浅层次盖层、火山物质与深层次TTG岩套的的反复剥露抬升。这种“北高南低”地貌特征的形成与阴山地体持续抬升及其两侧先存断裂活化密切相关,也是对周缘板块向东亚大陆俯冲汇聚的远程响应。

塔里木盆地西南部寒武系充填层序及沉积样式演化

针对塔里木盆地西南部寒武系存在的古隆起陆棚相分歧,利用锆石U-Pb(铀-铅同位素测年)年龄、井-震联合开展了寒武系层序充填与沉积演化的研究。研究表明:在巴楚隆起,寒武系直接覆盖在克拉通结晶基底之上,寒武系沉积充填与前寒武系结构呈“镜像”关系。受前寒武系地形、构造运动和海平面升降控制,塔里木盆地西南部寒武系发育4个Ⅱ级层序,分别为寒武系层序1(玉尔吐斯组—肖尔布拉克组)、寒武系层序2(吾松格尔组—沙依里克组)、寒武系层序3(阿瓦塔格组)、寒武系层序4(下丘里塔格群),共包含7个沉积相、10个沉积亚相。塔里木盆地西南部寒武系层序1—寒武系层序3早、中寒武世巴楚隆起—麦盖提斜坡—塔西南坳陷沉积相为台地—缓坡—斜坡—深水陆棚相沉积,表现为向海凝缩减薄的沉积特征并发育寒武系烃源岩;寒武系层序4晚寒武世塔里木盆地西南部主体演化为局限台地,塔里木盆地西台东盆沉积格局正式形成。

塔里木盆地哈拉哈塘—哈得地区中生界物源转换及沉积充填响应

通过矿物成分分析、砂地比计算、地震属性分析及测井响应特征识别等技术手段,对塔里木盆地哈拉哈塘—哈得地区中生界典型沉积时期的古地貌形态、沉积体系展布、地层及砂体发育特征等进行了研究。研究结果表明:(1)塔里木盆地哈拉哈塘—哈得地区三叠系物源主要来自东北部的天山造山带,其ZTR系数由东北部向凹陷中央逐渐增大;侏罗系和白垩系物源主要来自东南部和南部的昆仑山造山带,其ZTR系数由北部、南部向凹陷中央逐渐增大。(2)三叠纪晚期,随着古特提斯洋的增生,研究区北部天山的隆升强度减弱与南部昆仑山的隆升强度增大是此次物源转换的主要原因。(3)三叠纪,研究区的沉降-沉积中心位于南部,主要发育了一套北东—南西向的辫状河三角洲—深水湖泊沉积;侏罗纪和白垩纪,沉降-沉积中心则跃迁到研究区北部,主要发育了一套南东—北西向和南—北向的辫状河三角洲—浅水湖泊沉积。(4)三叠纪,砂体叠置样式的前积方向主要为北东—南西方向;侏罗纪和白垩纪,砂体叠置样式的前积方向主要为南东—北西方向和南—北方向。(5)三叠系岩性油气藏主要发育于研究区西南部,侏罗系和白垩系岩性油气藏主要发育于研究区西北部和北部。

松辽盆地南部青山口组沉积充填与铀矿找矿方向

随着钱家店矿区及外围铀矿带内的找矿空间越来越小,目前铀矿勘查工作对松辽盆地南部新区、新层位的找矿需求越来越大。为重新系统认识松辽盆地南部区域上的青山口组,文章通过大量钻孔岩心、测井资料,结合地质背景及前人研究成果,对松辽盆地南部青山口组的沉积充填特征进行了阐述,认为:研究区青山口组受坳陷盆地结构及中部架玛吐隆起的影响,区域上地层厚度变化较大,呈现凹隆相间的格局,整体表现为“中间薄、南北两侧厚;东部厚、西部整体缺失”的充填特征;研究区由南到北青山口组表现为冲积扇-河流-三角洲-湖泊的沉积体系,且以古隆起为界构成“南河北洲”的沉积格局;砂体主要发育于西南部开鲁坳陷内,且河道存在向中部古隆起、“鞍部”汇聚的特点,水流汇聚的区域即为目前有利灰色成矿砂体的发育部位。在此基础上,运用沉积学及砂岩型铀成矿理论对研究区铀矿找矿方向提出了两点建议:新增青山口组为研究区主攻目标层位,且其赋矿段具有由南往北不断上移的变化规律;将河流相河道汇水-砂体叠置部位及末端沉积相变部位、古隆起和凹陷的衔接部位、具古隆起“鞍状沟谷”格局汇水地貌特征的部位作为研究区砂岩型铀矿找矿方向。本研究首次全面系统地阐述了松辽盆地南部青山口组的沉积充填特征,完善了该地区基础地质理论研究,同时对扩大研究区找矿空间,有效支持科研生产具有指导意义。

川西南部地区下二叠统栖霞阶层序地层特征及岩相古地理

【目的】西接康滇古陆的四川盆地西南部下二叠统栖霞阶近年来展示出良好的勘探潜力,然而针对该地区地层充填规律及古地理格局的观点还并不统一,严重制约了下一步盆内精细的油气勘探和井位部署。【方法】以四川盆地西南部下二叠统栖霞阶梁山组和栖霞组为研究对象,综合利用野外剖面、钻井岩心和测录井等资料,在岩石类型与沉积相分析的基础上,运用海相碳酸盐岩层序地层学原理与方法,对栖霞阶层序界面进行识别。并采用单因素分析多因素综合作图法,以三级层序为编图单位,结合优势相原则,分别绘制研究区栖霞阶SQ0+SQ1和SQ2层序岩相古地理图。【结果】在栖霞阶中识别出4个三级层序界面,从下到上分别为梁山组底界面(I型)、栖一段内部界面(II型)、栖一段\栖二段界面(II型)和栖霞组\茅口组界面(I型),并将其划分为3个三级层序,每个层序均由海侵域和高位域组成。通过层序地层格架的对比分析,认为栖霞阶下部的SQ0层序大致对应于传统划分的梁山组+栖一段下部地层,仅发育于研究区内的栖霞阶地层沉积前古地貌低地,并且具有向古地貌高地超覆的层序充填特征,中部的SQ1层序和上部的SQ2层序则遍布全区。川西南栖霞阶层序岩相古地理格局总体上表现为西接康滇古陆的海相碳酸盐岩台地,古地貌和沉积相带分异比较明显,自西向东依次为:康滇古陆及其东缘的潮坪、台内洼地、台内丘滩体,以及开阔—半局限海台地,而且沿台内坡折带发育的台内丘滩体往往具有环洼规模分布的趋势。【结论】通过剖析台内坡折带对碳酸盐岩成储的影响,指出SQ2层序(栖二段)是研究区栖霞阶最有利于台内丘滩体这一潜力储集相带发育的层位,环台洼坡折带发育的丘滩体相带附近是有利的勘探区。从层序地层学角度重新认识栖霞阶充填模式及岩相古地理特征,为川西南部下二叠统栖霞阶的下一步储层预测及勘探开发提供全新的理论支撑。

Base level change and depositional filling response of Jurassic in the Qiangtang Basin of Tibet

The base level during the deposition of Jurassic in the Qiangtang Basin shows a complete cycle from rising to falling. The base level change is closely connected with tectonic evolution of the basin,especially connected with Bangonghu-Nujiang ocean evolution process in the formation and evolution of the basin. It is also affected by climate. The Jurassic strata correspond to a long-term base level cycle sequence. The sequence is in fact a non-complete symmetrical cycle,consisting of rising hemicycle and falling hemicycle. It can be divided into 6 intermediate-term base level cycle sequences,including 2 carbonate sequences,3 mixture sedimentary sequences of carbonate and clastic rocks and one clastic sedimentary sequence. Depositional filling characteristics during base level change show that Bangonghu-Nujiang ocean spreads in Toarcian-Bajocian ages,and is at the height of spreading of Bangonghu-Nujiang ocean in Bathonian-Oxfordian ages. In that process,sea area became smaller because of the dry climate. Eventually,marine depositional filling is ended with the subduction and collision of Bangonghu-Nujiang ocean.

渤中19-6气田变质岩储层热液型裂缝充填物及油气地质意义

渤海湾盆地渤中19-6气田是2018年勘探发现的特大型凝析气田。变质岩潜山储集系统中发育的裂缝是油气的主要渗流通道和储集空间,而裂缝充填物记录了储集层的流体作用及演化过程,故针对裂缝充填物的系统研究对于油气勘探开发具有重要意义。在系统观察渤中19-6气田典型岩芯铸体薄片的基础上,综合运用电子探针、LA-ICPMS、阴极发光和荧光分析等实验方法,分析裂缝充填物的地球化学特征及其与烃类物质的赋存关系,探讨研究区储层经历的热液活动和油气运移特点及热液活动对变质岩储层物性的影响。研究表明:1)热液型裂缝充填矿物主要由镁菱铁矿+铁白云石+石英、镁菱铁矿+石英、铁白云石+石英3种矿物组合构成;2)镁菱铁矿和铁白云石的原位微区地球化学特征显示其为同期热液流体成因;3)烃类物质主要为赋存于铁白云石中的束缚沥青和赋存于镁菱铁矿中的烃类包裹体,热液活动和油气运移具有同时性,属于同期发生的两类地质事件;4)热液流体对于储集岩裂缝的闭合作用远大于溶蚀扩张作用,对储集岩物性主要起破坏作用。