江西信江盆地白垩系沉积体系及其与丹霞地貌的关系

根据野外沉积层序、岩石学特征、古生物资料和地貌景观特征,本文对江西信江盆地白垩系沉积相进行了初步分析,首次探讨了沉积体系与丹霞地貌发育特征之间的内在联系。信江盆地白垩系主要发育4种沉积体系,即冲（洪）积、三角洲、湖泊和扇三角洲。早白垩世主要发育半深湖-深湖、扇三角洲相沉积,晚白垩世从盆地南缘到北缘大致为洪冲积相→辫状河流→三角洲→滨浅湖→三角洲→辫状河流→洪冲积相的展布方式。研究表明,该区丹霞地貌形成的物质基础主要是上白垩统冲积扇、辫状河相沉积产物,丹霞地貌的空间分布与盆地冲积扇、辫状河沉积相的平面展布具有较好的一致性,同时,沉积亚相、微相类型对丹霞地貌的发育起到一定的控制作用。     

琼东南盆地深水区烃源岩沉积模式及差异热演化

琼东南盆地深水区是目前的天然气勘探热点,但其烃源岩沉积模式和演化特征认识的不足制约了勘探成效.为识别和评价琼东南盆地深水区烃源岩,综合应用地震沉积学、有机地球化学及构造地质学分析方法,对比剖析渐新统含煤三角洲~浅海相泥岩的生烃母质、沉积背景及与已发现油气的对应关系.研究表明,渐新统三角洲的发育规模及古地貌控制了海陆过渡相煤系和海相陆源型烃源岩的分布,断-拗转换期凹凸相间的半封闭浅海环境有利于形成生气为主、油气兼生的渐新统海相陆源型烃源岩;深水区海相陆源型烃源岩分布、热演化及生排烃过程控制了天然气资源潜力,据此对生气凹陷进行分类评价并提出乐东、陵水及松南等Ⅰ类富生气凹陷.      

羌塘盆地查郎拉地区中生代岩相古地理初探

以实测剖面和路线地质填图剖面为基础,采用地层优势相 (亚相 )法和综合分析法首次系统地重建了羌塘盆地查郎拉地区中生代的岩相古地理。指出晚三叠世以海陆过渡相占主导地位,形成海退沉积旋回;由NE向SW依次出现三角洲相→滨岸相→滨浅海相带。中侏罗世浅海相沉积较发育,从NE向SW依次发育三角洲→台地相→浅海陆棚相带,呈NWW~SEE向展布,沉积中心应在中部偏西南侧,在J₂ q期和J₂ b期形成两次海侵高潮,总体组成两个由海侵→海退的沉积旋回。晚侏罗世海陆过渡相沉积较发育,从NE向SW依次发育三角洲相→潮坪相→台地相带,呈NW~SE向展布。白垩纪岩相古地理存在早晚差异 :早期为残留海背景下的台地边缘浅滩-局限台地相沉积,形成第三次海侵高潮;晚期全区迅速抬升,形成冲积扇~辫状河流相的磨拉石红色复陆屑沉积旋回及多物源供应格局。中生代沉积物源主要来自北部的中央隆起带,次为东部高地及西部隆起区;在沉积演化过程中,不同时代的沉积物源有所差别,且地形总体保持了北高南低、东高西低的格局。     

西秦岭临潭地区泥盆纪——三叠纪沉积环境恢复与盆地构造演化

根据西秦岭临潭地区泥盆纪—三叠纪沉积盆内细碎屑岩的主量、微量、稀土元素特征追溯源区背景,反演母岩性质,建立了该区沉积盆地与构造演化模式.认为沉积盆地的物源总体来自盆地的北部,北部经历了晚泥盆世的陆相—湖相沉积,石炭纪的滨岸海滩相-温暖潮湿的近岸海湾（潟湖或潮坪）相-浅海陆棚相沉积,到二叠纪的浅海陆棚-浅海陆棚内的堡礁或堤礁建造;沉积盆地南部为稳定的碳酸盐台地相.三叠纪,盆地经历了大陆斜坡浊流沉积—大陆斜坡（半深海）浊流沉积—滨浅海沉积环境复杂的环境变化.沉积盆地形成演化整体划分为3个阶段：被动大陆边缘台盆台地稳定发育阶段;弧后盆地形成演化阶段;弧后前陆盆地叠合阶段.     

广西百色盆地古近系始新统沉积相特征及演化

利用野外露头、地震、测井和分析化验等资料,对盆地古近系始新统那读组和百岗组进行层序地层和沉积相研究。那读组和百岗组可划分为3个Ⅲ级层序,9个体系域,那读组那三段构成层序Ⅰ,那读组那二段和那一段构成层序Ⅱ,百岗组构成层序Ⅲ。层序Ⅰ和层序Ⅱ是盆地断陷期沉积,发育冲积扇相、河流相、三角洲相、扇三角洲相、深湖亚相和滨-浅湖亚相。层序Ⅱ湖泊沉积范围广,厚度大,厚层的湖相暗色泥岩是盆地主要烃源岩和区域性盖层。层序Ⅲ是盆地坳陷期的沉积,发育冲积扇相、扇三角洲相、河流相、三角洲相和滨-浅湖亚相。盆地中古近系沉积经过了洪积或冲积扇、河流三角洲→湖泊（扇三角洲）→河流的发育过程,反映了盆地从初期形成→扩张→萎缩的完整的演化序列。在层序Ⅰ和层序Ⅱ的低水位体系域,田东凹陷的中央断凹、南部次凹和那笔凸起的北部断鼻等区带发育长轴分布的河流三角洲砂岩,这些砂岩处于烃源岩成熟区,油气成藏条件优越,是河道岩性油藏勘探的有利区。在层序Ⅱ湖侵体系域和高水位体系域,北部陡坡发育扇三角洲砂体,与烃源岩指状交叉接触,有利于油气运聚成藏,容易形成大量上倾尖灭岩性油藏。     

汾河裂谷晋中盆地内第四纪沉积序列与沉积环境恢复

晋中盆地是位于汾渭地堑系中部的新生代陆内断陷沉积盆地,研究晋中盆地第四纪的沉积序列对于进一步认识该盆地区域构造和区域气候环境变化具有重要意义。为查明晋中盆地第四纪沉积序列结构、研究揭示晋中盆地第四纪沉积环境及演化,通过构造岩相学方法,对晋中盆地地表和钻孔内第四纪沉积物和沉积环境进行了研究。结果表明:晋中盆地清徐地区地表第四纪沉积序列结构为盆地内部沱阳组河床相和河漫滩相-盆地边缘汾河组河流相—盆山过渡带峙峪组河流相、汾河组冲积扇相及马兰组风积相-基岩山地（盆地外围）二叠系浅海相。钻孔岩芯内第四纪沉积序列结构为下更新统浅湖相和滨湖相—中更新统浅湖相和河流相—上更新统河流相和冲积扇相—全新统冲积扇相。研究认为晋中新生代陆内断陷盆地内沉积序列和演化结构为早更新世陆相湖盆沉积环境—中更新世萎缩湖泊环境—晚更新世强烈萎缩的湖泊和河流环境—全新世再度沉降的陆相湖盆;陆相湖盆从中心向山地沉积环境分带为湖泊沉积环境—河流和湖泊沉积环境—冲积扇沉积环境（盆地边缘出山口区）。盆山过渡带地区上更新世沉积物错位现象与同沉积活动断裂有关,断裂活动性揭示了晋中盆地阶梯式断陷成盆的动力学机制。这些研究成果为区域气候环境变化和晋中盆地区域构造研究提供了新证据,也为太原市城市群建设中工程场址的选择提了供参考。      

藏南地区晚白垩世岩相古地理初步研究

通过对藏南地区上白垩统沉积特征及沉积相进行综合分析,初步地恢复了该地区晚白垩世岩相古地理.该地区自南向北沉积水体逐步变深,沉积相带展布依次为滨海相、浅海陆棚相(外陆棚和内陆棚亚相)、大陆斜坡相及深海盆地相,局部地区浅海陆棚相之上发育碳酸盐岩礁滩相和孤立台地相等.盆地性质总体上仍然为被动大陆边缘海盆,但已具备周缘前陆盆地...     

黑龙江三江地区晚古生代沉积环境演化

为深刻理解三江地区前白垩纪地层序列、岩相古地理面貌以及原型盆地构造运动与沉积演化的关联问题,笔者将研究区分为佳木斯地块与那丹哈达地体两部分,建立了佳木斯地块的地层序列。利用岩性、粒度和沉积构造等特征识别出中泥盆统黑台组、上石炭统珍子山组和下二叠统二龙山组的浅海相、三角洲相--湖泊相和火山相等主要沉积类型,恢复对应的岩相古地理面貌。佳木斯地块晚古生代经历了被动大陆边缘-主动大陆边缘的构造演化,发育弧后盆地;那丹哈达地体曾有浅海--深海盆地,现为增生或杂岩体,那丹哈达地体与佳木斯地块的相对运动控制了晚古生代沉积环境和盆地演化。     

中扬子地区中二叠统沉积及古地理特征

中扬子地区中二叠世为广海盆地,地层总体南厚北薄,岩相呈渐变关系,从南到北由浅海相的灰岩向半深海及深海相的硅质灰岩、硅质岩转变,沉积水体南浅北深.从微相分析的角度证明了在研究区中二叠统广泛发育的砾屑灰岩为异地沉积成因,而非差异压实成因.栖霞期研究区遭受广泛海侵,中扬子北缘为外缓坡-盆地沉积,中扬子克拉通主体为缓坡沉积,局...     

江汉盆地潜江凹陷古近系盐湖沉积盐韵律及其古气候意义

盐湖沉积具有成盐多期性和长期性、沉积连续性、淡化-咸化周期性等特色,因而成为在恢复古气候环境、进行全球变化研究的重要研究对象之一。本文以我国东部独具特色的古近纪古盐湖盆地--江汉盆地潜江凹陷潜江组盐韵律为例,通过对王平1等3口井连续取心段的精细研究,在前人划分Ⅰ、Ⅱ、Ⅲ级盐韵律的基础上,首次划分出组成含盐层系基础韵律单元--Ⅳ级盐韵律,弄清了其沉积过程基本遵循从盐岩→（含泥）钙芒硝岩→含云泥岩（含泥云岩）→泥岩→白云岩→钙芒硝岩→盐岩的淡化-咸化序列和盐类矿物的析出顺序;解析了Ⅳ级盐韵律及其沉积组合记录与水体古盐度波动和短尺度（0.05ka -1.0ka）古气候干-湿变化之间的对应关系。根据典型暖相盐类矿物原生钙芒硝及其薄层在潜江组中广泛发育,可以推断江汉盆地流域在晚始新世-早渐新世潜江组沉积期间,所出现的干旱古气候背景属于暖旱型而非寒旱型。     

南海陆缘盆地构造演化与烃源岩特征

受近南北向扩张机制控制,南海陆缘盆地或凹陷多呈NE向带状展布,总体上具有“南三北三”平行排列、外窄内宽的特点。新生代发生的4次重要区域构造运动具有穿时性,共发育3期盆地破裂不整合面,分别是早渐新世与晚渐新世之间、古近纪与新近纪之间、中中新世与晚中新世之间;由东往西,盆地破裂不整合面的时代逐渐变新。受构造运动与海平面升降影响,南海海域发育湖相、海陆过渡相和陆源海相3类烃源岩。由南北两侧向中央海盆,烃源岩类型由湖相逐渐过渡到海陆过渡相与陆源海相;从东向西,盆地主力烃源岩层位逐渐变新,由始新统-渐新统逐渐过渡到渐新统-中新统。南海海域烃源岩的分布规律与盆地破裂不整面存在密切关系:破裂不整合面形成早（早渐新世与晚渐新世之间）的盆地,主力烃源岩形成早（始新统湖相烃源岩）;反之,破裂不整合面形成晚（中中新世与晚中新世之间）的盆地,则烃源岩形成晚（渐新统-中新统海陆过渡相到陆源海相烃源岩）。     

南海西南部北康盆地新生代沉积演化史

北康盆地位于南沙地块的西南边缘，为南沙中部海域的新生代沉积盆地，具有良好的含油气潜力。近年广州海洋地质调查局在盆地六万多平方千米范围内完成了近2000km的地震测线，及相应的重力与磁力测量。本文在区域地质背景分析基础上，对盆地进行了地震地层对比和详细的地震相分析，划分了3个超层序、7个层序，对其中的5个层序进行了沉积相分析，并编制了沉积相平面图。晚始新世以前，北康盆地位于古南海西北缘，盆地西北部为陆相环境。东南部为滨－浅海环境。晚始新世－早渐新世早期，南沙地块从华南陆块裂离向南漂移，随古南海洋带的被动消减和新南海的扩张，盆地水体加深，除西北尚有陆相沉积外，主要为海相环境。早渐新世后，南沙地块与婆罗州地块拼贴，北康盆地逐渐处于浅海－半深海环境。与盆地沉积演化规律相对应，早第三纪发育的湖相和沼泽相泥岩及早中新世发育的浅海相泥岩为有利烃源岩， 同期的三角洲相砂岩、滨海相砂岩及晚中新世发育的浊积岩为主要储层，区域性盖层为晚各新世以来的 浅海－半深海相泥岩、砂质泥岩、局部性盖层有湖相泥岩、浅海相砂质泥岩、泥岩和灰质泥岩。     

东海陆架盆地南部油气资源前景与选区

通过开展二维地震资料调查和重处理,结合钻井、重磁、海陆对比等新老资料开展联合解释认为:东海陆架盆地南部中生界具有分布广、厚度大、沉积中心位于东部,新生界则呈现东西厚中间薄,新生代构造单元中的台北凸起、观音凸起和雁荡凸起上均有中生界分布;白垩系较侏罗系分布更为广泛,侏罗系西部边界为雁荡凸起东侧,白垩系西部边界以瓯江凹陷西侧为界;中生界三口钻井分析结果发现了确凿的海相标志,证实了中生界东海陆架盆地发生多次海侵,结合围区沉积特征认为侏罗纪存在南北向和东西向的海侵,白垩纪主要体现为东西向的海侵;研究区中生界发育中下侏罗统、下白垩统两套烃源岩,新生界发育古新统、始新统、渐新统和中新统四套烃源岩,具有较好的油气资源前景。     

Geological evolution of the Iraqi Mesopotamia Foredeep,inner platform and near surroundings of the Arabian Plate

The Iraqi territory could be divided into four main tectonic zones; each one has its own characteristics concerning type of the rocks, their age, thickness and structural evolution. These four zones are: (1) Inner Platform (stable shelf), (2) Outer Platform (unstable shelf), (3) Shalair Zone (Terrain), and (4) Zagros Suture Zone. The first two zones of the Arabian Plate lack any kind of metamorphism and volcanism.The Iraqi territory is located in the extreme northeastern part of the Arabian Plate, which is colliding with the Eurasian (Iranian) Plate. This collision has developed a foreland basin that includes: (1) Imbricate Zone, (2) High Folded Zone, (3) Low Folded Zone and (4) Mesopotamia Foredeep.The Mesopotamia Foredeep, in Iraq includes the Mesopotamia Plain and the Jazira Plain; it is less tectonically disturbed as compared to the Imbricate, High Folded and Low Folded Zones. Quaternary alluvial sediments of the Tigris and Euphrates Rivers and their tributaries as well as distributaries cover the central and southeastern parts of the Foredeep totally; it is called the Mesopotamian Flood Plain. The extension of the Mesopotamia Plain towards northwest however, is called the Jazira Plain, which is covered by Miocene rocks.The Mesopotamia Foredeep is represented by thick sedimentary sequence, which thickens northwestwards including synrift sediments; especially of Late Cretaceous age, whereas on surface the Quaternary sediments thicken southeastwards. The depth of the basement also changes from 8 km, in the west to 14 km, in the Iraqi–Iranian boarders towards southeast.The anticlinal structures have N–S trend, in the extreme southern part of the Mesopotamia Foredeep and extends northwards until the Latitude 32°N, within the Jazira Plain, there they change their trends to NW–SE, and then to E–W trend.The Mesozoic sequence is almost without any significant break, with increase in thickness from the west to the east, attaining 5 km. The sequence forms the main source and reservoir rocks in the central and southern parts of Iraq. The Cenozoic sequence consists of Paleogene open marine carbonates, which grades upwards into Neogene lagoonal marine; of Early Miocene and evaporitic rocks; of Middle Miocene age, followed by thick molasses of continental clastics that attain 3500 m in thickness; starting from Late Miocene. The Quaternary sediments are very well developed in the Mesopotamia Plain and they thicken southwards to reach about 180 m near Basra city; in the extreme southeastern part of Iraq.The Iraqi Inner Platform (stable shelf) is a part of the Arabian Plate, being less affected by tectonic disturbances; it covers the area due to south and west of the Euphrates River. The main tectonic feature in this zone that had affected on the geology of the area is the Rutbah Uplift; with less extent is the Ga’ara High.The oldest exposed rocks within the Inner Platform belong to Ga’ara Formation of Permian age; it is exposed only in the Ga’ara Depression. The Permian rocks are overlain by Late Triassic rocks; represented by Mulussa and Zor Hauran formations, both of marine carbonates with marl intercalations. The whole Triassic rocks are absent west, north and east of Ga’ara Depression. Jurassic rocks, represented by five sedimentary cycles, overlie the Triassic rocks. Each cycle consists of clastic rocks overlain by carbonates, being all of marine sediments; whereas the last one (Late Jurassic) consists of marine carbonates only. All the five formations are separated from each other by unconformable contacts. Cretaceous rocks, represented by seven sedimentary cycles, overlie the Jurassic rocks. Marine clastics overlain by marine carbonates. Followed upwards (Late Cretaceous) by continental clastics overlain by marine carbonates; then followed by marine carbonates with marl intercalations, and finally by marine clastics overlain by carbonates; representing the last three cycles, respectively.The Paleocene rocks form narrow belt west of the Ga’ara Depression, represented by Early–Late Paleocene phosphatic facies, which is well developed east of Rutbah Uplift and extends eastwards in the Foredeep. Eocene rocks; west of Rutbah Uplift are represented by marine carbonates that has wide aerial coverage in south Iraq. Locally, east of Rutbah Uplift unconformable contacts are recorded between Early, Middle and Late Eocene rocks. During Oligocene, in the eastern margin of the Inner Platform, the Outer Platform was uplifted causing very narrow depositional Oligocene basin. Therefore, very restricted exposures are present in the northern part of the Inner Platform (north of Ga’ara Depression), represented by reef, forereef sediments of some Oligocene formations.The Miocene rocks have no exposures west of Rutbah Uplift, but north and northwestwards are widely exposed represented by Early Miocene of marine carbonates with marl intercalations. Very locally, Early Miocene deltaic clastics and carbonates, are interfingering with the marine carbonates. The last marine open sea sediments, locally with reef, represent the Middle Miocene rocks and fore reef facies that interfingers with evaporates along the northern part of Abu Jir Fault Zone, which is believed to be the reason for the restriction of the closed lagoons; in the area.During Late Miocene, the continental phase started in Iraq due to the closure of the Neo-Tethys and collision of the Sanandaj Zone with the Arabian Plate. The continental sediments consist of fine clastics. The Late Miocene – Middle Pliocene sediments were not deposited in the Inner Platform.The Pliocene–Pleistocene sediments are represented by cyclic sediments of conglomeratic sandstone overlain by fresh water limestone, and by pebbly sandstone.The Quaternary sediments are poorly developed in the Inner Platform. Terraces of Euphrates River and those of main valleys represent pleistocene sediments. Flood plain of the Euphrates River and those of large valleys represent Holocene sediments. Residual soil is developed, widely in the western part of Iraq, within the western marginal part of the Inner Platform.     

南海西北次海盆构造演化的沉积响应

通过对南海西北次海盆新获得的地震资料进行综合解释和层序地层分析,揭示了海盆中的沉积对构造演化阶段的响应。始新世-早渐新世陆缘裂陷期,盆地以对称裂谷形式,发育地堑裂谷层序,沉积以近物源为特征,相变大,发育了冲积扇-扇三角洲-湖相沉积,沉积体系的配置受同沉积断裂控制明显,快速沉降和充分的物源供给决定了沉积体系的构成特征。晚渐新世海底扩张期,岩石圈破裂,陆缘进一步拉开并开始海底扩张,出现海相沉积,来自陆坡的陆架边缘三角洲越过陆坡进入海盆,在海盆内沉积了一套向海盆中部逐渐减薄的楔状地层,并伴有大量的火山碎屑沉积物。早-中新世以来热沉降期,随着构造沉降增大,相对海平面总体不断上升,进入深水盆地,形成陆架陆坡体系,大量的碎屑物质以重力流、深水底流等深水作用方式进入海盆;沉降晚期陆架-陆坡物源供应减弱,琼东南中央峡谷成为其主要的物质供应来源通道,在此期间二次海平面下降、回升的综合作用下,海盆内发育了多期以下切水道为特征的低水位域沉积体系。     

Facies analysis and depositional systems of Cenozoic sediments in the Hoh Xil basin, northern Tibet

A sedimentary succession more than 5800 m thick, including the Lower Eocene to Lower Oligocene Fenghuoshan Group, the Lower Oligocene Yaxicuo Group, and the Lower Miocene Wudaoliang Group, is widely distributed in the Hoh Xil piggyback basin, the largest Cenozoic sedimentary basin in the hinterland of the Tibetan plateau. The strata of the Fenghuoshan and Yaxicuo groups have undergone strong deformation, whereas only minor tilting has occurred in the Wudaoliang Group. We analyze their sedimentary facies and depositional systems to help characterize continental collision and early uplift of the Tibetan plateau. The results indicate fluvial, lacustrine, and fan-delta facies for the Fenghuoshan Group, fluvial and lacustrine facies for the Yaxicuo Group, and lacustrine facies for the Wudaoliang Group. Development of the Hoh Xil basin underwent three stages: (1) the Fenghuoshan Group was deposited mainly in the Fenghuoshan-Hantaishan sub-basin between 56.0 and 31.8 Ma ago; (2) the Yaxicuo Group was deposited mainly in the Wudaoliang and Zhuolai Lake sub-basins between 31.8 and 30.0 Ma ago; and (3) the Wudaoliang Group was deposited throughout the entire Hoh Xil basin during the Early Miocene. The Fenghuoshan and Yaxicuo groups were deposited in piggyback basins during the Early Eocene to Early Oligocene, whereas the Wudaoliang Group was deposited in a relatively stable large lake. The Hoh Xil basin underwent two periods of strong north–south shortening, which could have been produced by the collision between India and Asia and the early uplift of the Tibetan plateau. The study suggests the Hoh Xil region could reach a high elevation during the Late Oligocene and the diachronous uplift history for the Tibetan plateau from east to west.     

安徽明光盆地第三系层序地层学分析

安徽明光盆地第三纪沉积物以陆相红色类磨拉石建造为主 ,晚期覆盖陆相火山岩建造 ,通过对陆相红色类磨拉石建造的分析表明其形成于冲积扇和扇前河湖环境。在对明光盆地内各类陆相沉积建造的沉积环境、沉积相、陆相沉积体系域和地层层序界面的分析基础上 ,根据盆地的充填沉积序列划分出 5个层序 (三级层序 ) ,由于受到构造运动的影响 ,其层序发育皆不完整。在对其进行层序地层学分析的基础上 ,初步建立了明光盆地的地层格架。     

Simulation of temporal variation for reference evapotranspiration under arid climate

Interpretation of 2500 km of newly processed 2D seismic and regional potential field data has led to the identification of two new Miocene–Oligocene sedimentary basins in the northern part of offshore Egypt. The western part of the basin is deeper and has thick sedimentary cover. The upper part of the Miocene section is tested in its southern part through two wells, where the eastern subbasin is still virgin and is located at the intersection between Temsah basins and southeastern end of the Levantine basin. The main sedimentary unit of the basin is the Miocene–Oligocene sedimentary section, which was proven by the exploration and production activities in Nile Delta to be one of the hydrocarbon-generating facies. This fact is supported by 1D basin analysis using the average parameter values, which shows a hydrocarbon window, extending from lower Miocene to upper Miocene. The basin dimensions are more than 2000 km² area and more than 4000 m of thickness, with variable petroleum system parameters’ potentialities, starting from Tortonian–Serravallian to lower Oligocene section.

     

四川盆地寒武纪岩相古地理特征

通过露头、岩心、钻测井资料分析建立典型沉积相序列,结合单因素分析综合作图,编制了四川盆地寒武纪各个时期的岩相古地理图件。盆地整体西高东低、西部发育陆源碎屑沉积,中东部以碳酸盐岩沉积为主。寒武纪包含两个半海侵—海退旋回:首次海侵发生在早寒武世筇竹寺期,形成巨厚的浅海陆棚相泥质烃源岩;首次海退发生在早寒武世沧浪铺期,陆源碎屑供给充足,发育三角洲和碎屑滨岸相沉积;第二次和第三次海侵发生在早寒武世龙王庙期与中晚寒武世洗象池期,为碳酸盐岩滩相储层发育的主要时期,在局限台地的地形较高部位发育砂砾屑滩和鲕粒滩,砂砾屑滩主要发育在盆地的中西部,鲕粒滩主要发育在盆地的中东部,在盆地西南部发育具有继承性的泻湖相沉积。     

莺-琼盆地海相烃源岩特征及高温高压环境有机质热演化

莺歌海盆地与琼东南盆地存在渐新统海岸平原-半封闭浅海相和中新统浅海相两套海相烃源岩。其中,渐新统烃源岩发育于琼东南盆地早第三纪半地堑,存在海岸平原和半封闭浅海两类烃源岩组合。海岸平原含煤烃源岩有机质丰度高,富含陆源有机质,具有很好的生气潜力;半封闭浅海相烃源岩TOC含量总体低于1.0%,但其规模大且存在TOC1.5%的较高丰度段,故亦具有较大的生气能力。中新统海相烃源岩主要分布于莺歌海盆地裂后热沉降形成的中央坳陷,其有机质丰度横向变化比较大,位于中央坳陷带的烃源岩有机质丰度较高,TOC大多在0.40%～2.97%之间,有机质以气型干酪根为主。盆地的高地温为有机质向天然气转化提供了有利的条件,尤其是热流体活动使浅层有机质超前熟化,但地层超压对有机质热演化也有一定的抑制作用。盆地模拟结果显示,莺-琼盆地主要凹陷烃源岩大量生气时间较晚,与圈闭形成期的时空配置好,有利于成藏。