琼东南盆地北礁凹陷梅山组顶部丘形反射特征及成因分析

南海琼东南盆地北礁凹陷中中新统梅山组顶部丘形反射目前引起广泛关注,前人推测为生物礁、重力蠕动与底流叠加成因、等深积丘等。本文通过钻井资料、二维、三维地震资料精细刻画丘形反射（残丘）和丘间水道特征及其成因。残丘及水道在北礁凸起不发育,在边缘斜坡中部和高地较发育,且有向高地两边规模减小趋势,不具对称性,残丘和水道呈平行-亚平行近E-W向展布,局部有合并分叉现象,与北礁凸起走向呈一小角度;丘宽562~1 223 m,丘高29~87 m,丘长10 km左右,存在丘翼削蚀,水道底蚀现象。地震属性分析表明三维工区西南部残丘间水道由砂泥岩互层充填,形成长条形强振幅,而残丘为中-低振幅;地震、钻井资料分析表明丘形反射（残丘）由钙质泥岩和泥岩组成,属于半深海沉积,且残丘内部波阻抗为5.0×106~6.5×106kg/m3·m/s,低于火山岩、灰岩波阻抗,属于砂泥岩地层范畴;根据梅山组下段水道由西向东强振幅变弱、分叉、前积反射和海山附近底流（等深流）沉积剥蚀特征综合判定底流古流向自西向东,根据海山两翼地震反射特征推测底流可追溯至晚中新世早期（11.6 Ma BP）,综合分析认为,研究区中中新统梅山组丘形反射是晚中新世早期底流切割梅山组地层形成的残丘。     

琼东南盆地南部中新统“丘”形反射成因探讨

在琼东南盆地南部中新统梅山组广泛发育“丘”形反射, 对其识别分析具有重要的意义。这些“丘”形反射主要分布在北礁凹陷及周缘斜坡带上, 在顶底界面呈强反射, 在内部成层、杂乱或为空白反射, 有时在顶部见披覆沉积, 从盆地中心北礁凹陷向边缘斜坡带迁移生长。通过对“丘”形反射的古构造和古地理背景、几何学特征及地震响应特征等方面综合分析, 对其成因进行了探讨, 排除了其为生物礁、泥底辟以及火山丘的可能, 认为其可能为深水环境底流作用下形成的等深流沉积或某种沉积物波。     

南海北部深水区中新世生物礁发育特征

基于近些年南海北部深水区采集的地震资料,对南海北部深水区中新世生物礁发育特点进行分析、对比和研究,认为西沙隆起地区发育典型的生物礁,具有丘状反射、强振幅、中频、中连和杂乱地震相,发现琼东南盆地北礁地区在中新世梅山组也有似礁相发育.通过对琼东南盆地深水区中新世生物礁层序地层学分析,认为生物礁在中新世梅山组海侵体系域和高位体系域发育.从对北礁地区典型生物礁剖面进行的波阻抗反演来看,其与LH11-1生物礁油田的波阻非常相似,波阻抗值为8×106-9×106kg/(m2·s).古地理分析认为,中新世西沙隆起区与北礁地区处于滨、浅海沉积环境,梅山组时期的陆缘碎屑供给量比较少,适于生物礁发育.     

断陷湖盆水道型湖底扇沉积储层预测——以莱州湾凹陷沙三中亚段为例

渤海湾盆地莱州湾凹陷沙三段发育大型水道型湖底扇岩性圈闭，成藏背景较好，勘探潜力较大，但湖底扇沉积特征不明确，储层分布难以精细刻画，制约了勘探的进程。因此，在地震沉积学、沉积学理论指导下，提出了以不同重力流水道类型地震相分析为基础优选敏感属性，平面剖面结合精细刻画湖底扇的展布，最终确立有利储层发育区的技术思路，以期为研究区湖底扇型岩性油气藏勘探部署提供有利的支持。分析认为，湖底扇水道具有中-弱振幅、杂乱反射特征，与湖相泥岩的平行连续、强振幅反射具有明显差异，以此为基础优选分频倾角相干和基于灰度共生矩阵的地震结构属性及神经网络波形分类技术对湖底扇边界以及内幕水道进行刻画。其中，限制水道复合体及叠置水道复合体砂岩厚度大，两类水道发育区域是研究区的有利储层发育区。限制水道复合体分布在F1断裂坡折带下，水道厚度及宽度较大；叠置水道复合体分布在F2断裂坡折带下。     

琼东南盆地北礁凹陷上新统等深流影响的水道沉积体系

等深流影响的水道沉积体系的沉积特征及其沉积过程是当前深水沉积学研究的热点、难点和前沿科学问题,但研究程度较为薄弱。该文以北礁凹陷上新统（地震反射T20?T30）为研究对象,利用覆盖北礁凹陷局部的三维地震资料,采用均方根属性、相干属性、时间域构造,再结合地震切片等方法,研究北礁凹陷深水区上新统斜交斜坡（走向）的特殊水道沉积体系特征及其沉积过程。研究发现,该水道沉积体系分为早、晚两期,早期发育水道和片状、扇状溢堤沉积,晚期仅发育水道和片状溢堤沉积,其中扇状溢堤沉积仅发育在水道右侧弯曲处,片状溢堤沉积仅分布在水道左侧,水道始终与区域斜坡斜交,水道对称分布且无明显迁移现象。结合该时期北礁凸起发育等深流相关的丘状漂积体和环槽,认为该水道沉积体系特殊的形态主要受控于等深流与浊流交互作用的沉积结果:浊流流经水道,其上覆浊流溢出水道,形成溢岸浊流,在水道左侧,该溢岸浊流与等深流发生相向运动,被等深流“吹拂”到单侧,大面积分布,延伸千米,形成片状溢堤沉积;而在水道弯曲处（右侧）,溢岸浊流与等深流发生相对运动,抑制溢岸浊流进一步扩展,形成相对小范围扇状溢堤沉积,该沉积结果与前人水槽实验结果相一致。     

南海白云凹陷东南部两种不同类型块体搬运沉积体系的地震响应及成因分析

文章利用三维地震数据揭示了南海白云凹陷东南部两种不同类型的块体搬运沉积体系的内部反射特征、外部形态及运动指示标志, 并且探讨了其成因机制。结果表明, 自晚中新世以来研究区共发育4种地震相: 弱振幅水平状连续地震相、强振幅波状连续地震相、弱振幅半透明杂乱反射地震相和中-强振幅丘状连续反射地震相。通过地震相分析可知, 研究区自晚中新世以来共发育两种不同类型的块体搬运沉积体系: 1) 多期块体搬运沉积复合体, 主要由弱振幅半透明杂乱反射地震相组成, 边界模糊; 2) 单期块体搬运沉积体, 主要由弱振幅半透明杂乱反射地震相和中-强振幅丘状连续反射地震相组成, 边界清晰明显。另外, 研究结果发现高沉积速率和地震活动使得研究区的块体搬运沉积体系表现出内部运动指示特征发育程度低的特征, 而东沙构造活动导致该块体搬运沉积体系具有频发性。     

琼东南盆地北礁凹陷梅山组单向迁移水道特征及成因探讨

深水区重力流与底流交互作用的过程、响应及动力学机制是海洋沉积学研究的前沿和薄弱环节。本文通过三维地震资料，在深水区北礁凹陷南西部梅山组发现多条相间分布的长条形顺直强振幅水道，垂直于西沙隆起（南部隆起）北斜坡走向，向南西方向单向迁移，水道具有南西陡（凹岸或陡岸）北东缓（凸岸或缓岸）的特征，该类水道分为侵蚀界面和水道砂-堤岸泥过渡复合体系两个单元，侵蚀界面在凹岸的削截反射明显多于凸岸，水道砂-堤岸泥过渡复合体振幅强度由凹岸强振幅逐渐过渡为凸岸弱振幅。分析认为，该类水道发育于中中新世半深海环境，不同于向底流下游方向单向迁移的峡谷，它们向底流上游方向发生单向迁移，并提出其成因模式:前期来自南部的浊流下切形成负向地貌单元（水道），底流对这一地貌单元进行改造，形成迎流面缓（凸岸）背流面陡（凹岸）的地貌，同时驱使浊流上部顺底流方向偏移，形成溢岸浊流沉积，致凹岸沉积速率低，凸岸沉积速率高，这样就迫使水道逆底流方向偏移。沉积物源、中层水相关底流、古气候和海平面的变化、北礁凸起古地形控制是该区单向迁移强振幅水道发育的因素。本研究在南海首次发现这种向底流上游方向单向迁移的水道，是底流与重力流交互作用的新型类型，对古海洋、古气候研究，深水油气勘探有着重要的意义，希望引起地质学家的重视。     

东海丽水凹陷西次凹明月峰组海底扇沉积特征及沉积模式

东海陆架盆地丽水凹陷古新统明月峰组发育典型的海底扇沉积,且已获得工业油气发现。该文利用现有地震地质资料,运用层序地层学理论方法,总结出丽水凹陷的海底扇沉积模式。海底扇沉积相标志包括:岩心主要表现为滑塌揉皱、包卷层理、泄水构造、块状砂岩、黑色泥岩撕裂屑、漂砾、砂注等构造;C-M图主要表现为重力流沉积特征;结构成熟度和成分成熟度中等—差。扇体地震反射结构主要为顺物源方向双向下超,垂直物源方向丘状反射特征,平面地震属性显示为典型扇形。丽水凹陷明月峰组由低位体系域、水进体系域和高位体系域组成,其中海底扇发育在低位体系域,在扇体近端发育多个下切谷,下切谷下切规模较大;坡折主要划分为断裂坡折和沉积坡折,其中断坡坡度较大,坡度7.2°左右,沉积坡折坡度较小,一般在5°左右,与下切谷相对应在谷口形成一系列的扇体,沟–坡–扇耦合关系良好。扇体规模较大,单个扇体面积最大124 km2,整个低位域由6个扇体组成,展示了丽水凹陷良好的岩性圈闭勘探前景。本次研究根据扇体的成因特点建立明月峰组低位域时期沟–坡–扇沉积模式,对指导勘探寻找出岩性圈闭和开创丽水凹陷油气勘探新局面具有一定意义。     

西沙海区碳酸盐台地地震反射特征及沉积模式

随着南海海盆的持续扩张,西沙海区整体沉降,从早中新世起西沙碳酸盐台地开始发育,而且在台地之上生长了不同类型的生物礁。通过地震识别认为,西沙海区生物礁在地震剖面上表现为顶底强振幅的丘形连续反射、内部弱振幅杂乱反射;碳酸盐台地表现为顶部强振幅连续平行反射、底部界面局部模糊、内部强弱相间亚平行连续反射。通过对西沙海区地层层序的分析以及大量地震资料的解释认为,在西沙碳酸盐台地的发育早期它受基底构造的控制,而在后期主要受多期海平面变化的影响,其发育演化经历了初始生长—加积—出露—二次生长—淹没等一系列阶段,复杂的演化过程也使西沙碳酸盐岩具有较好的储集条件和油气远景。     

南海北部揭阳凹陷天然气水合物的地震异常特征分析

大量研究表明南海北部珠江口盆地是天然气水合物发育区,但是该盆地东部揭阳凹陷水合物研究较少。本文利用揭阳凹陷新采集三维地震资料,对该三维地震资料进行成像道集优化和叠前时间偏移处理,得到针对水合物的新处理地震数据体,并通过高精度网格层析反演得到层速度数据体。利用该数据开展叠后约束稀疏脉冲反演,获得含天然气水合物地层波阻抗异常,综合分析反演与地震属性识别水合物。从新处理地震资料看,该区域似海底反射(bottom simulation reflection,BSR)反射呈连续、不连续与地层斜交等特征,BSR发育在一个继承性小型水道上,且下部断裂和气烟囱发育。通过分析BSR特征及BSR上下地层的速度、波阻抗、振幅、频率、相干等属性异常,结合水合物成藏条件,发现了南海北部新的天然气水合物有利富集区,为该区域水合物勘探提供基础。     

Characteristics and origins of middle Miocene mounds and channels in the northern South China Sea

Numerous elongated mounds and channels were found at the top of the middle Miocene strata using 2D/3D seismic data in the Liwan Sag of Zhujiang River Mouth Basin(ZRMB) and the Beijiao Sag of Qiongdongnan Basin(QDNB). They occur at intervals and are rarely revealed by drilling wells in the deepwater areas. Origins of the mounds and channels are controversial and poorly understood. Based on an integrated analysis of the seismic attribute, palaeotectonics and palaeogeography, and drilling well encountering a mound, research results show that these mounds are dominantly distributed on the depression centres and/or slopes of the Liwan and Beijiao sags and developed in a bathyal sedimentary environment. In the Liwan and Beijiao sags, the mounds between channels(sub) parallel to one another are 1.0–1.5 km and 1.5–2.0 km wide, 150–300 m and 150–200 m high, and extend straightly from west to east for 5–15 km and 8–20 km, respectively. Mounds and channels in the Liwan Sag are parallel with the regional slope. Mounds and channels in the Beijiao Sag, however, are at a small angle to the regional slope. According to internal geometry, texture and external morphology of mounds, the mounds in Beijiao Sag are divided into weak amplitude parallel reflections(mound type I), blank or chaotic reflections(mound type II), and internal mounded reflections(mound type Ⅲ). The mounds in Liwan Sag, however, have the sole type, i.e., mound type I. Mound type I originates from the incision of bottom currents and/or gravity flows. Mound type II results from gravity-driven sediments such as turbidite. Mound type Ⅲ is a result of deposition and incision of bottom currents simultaneously. The channels with high amplitude between mounds in the Beijiao and Liwan sags are a result of gravity-flow sediments and it is suggested they are filled by sandstone.Whereas channels with low-mediate amplitudes are filled by bottom-current sediments only in the Beijiao Sag,where they are dominantly composed of mudstone. This study provides new insights into the origins of the mounds and channels worldwide.     

Seafloor and buried mounds on the western slope of the Niger Delta

Seafloor mounds are potential geohazards to offshore rig emplacement and drilling operations and may contain evidence of underlying petroleum systems. Therefore, identifying and mapping them is crucial in de-risking exploration and production activities in offshore domains.A 738 km² high resolution three-dimensional seismic dataset was used to investigate the occurrence, seismic characteristics and distribution of features interpreted as seafloor and buried sediment mounds, at water-depths of 800–1600 m, on the western Niger Delta slope. Fifteen seafloor mounds and eighteen shallowly buried mounds were identified. The seafloor mounds are characterised by lower seismic amplitude anomalies than the surrounding seabed sediments, and overlie vertical zones of acoustic blanking. The buried mounds in contrast are characterised by high amplitude anomalies; they also directly overlie sub-vertical zones of acoustic blanking. Seismic evidences from the features, their distribution patterns and tectono-stratigraphic associations suggest that their formation was controlled by the juxtaposition of buried channels and structural highs and their formation caused by focused fluid flow and expulsion of entrained sediments at the seabed.Considering the acoustic and geometrical characteristics of the mounds and comparing them with mound-shaped features from around the world, we conclude that the mounds most likely comprise heterolithic seafloor extrusions of muds and sands from the Agbada Formation with gas and possibly oil in some of the pore space giving rise to the acoustic characteristics.     

西沙海域碳酸盐台地周缘水道沉积体系

高分辨率地震资料显示,南海北部西沙海域碳酸盐台地周缘广泛发育水道沉积体系。礁缘水道底界面表现出强反射特征,内部充填弱-强、连续性好的地震相,可见底部杂乱反射特征;斜坡水道在地震剖面上表现为横向上连续发育的"V"型特征,且下切深度较浅。西沙隆起与广乐隆起之间的南北向低洼地带发育大型深水水道,并且受古地貌高点影响,水道分为南北两个分支。北分支水道可分为5期,且水道迁移现象明显;南分支水道可分为4期,水道以充填强振幅、连续性好的浊流沉积体和弱振幅、杂乱的块体搬运体系(Mass Transport Deposits,MTDs)为特征,每期水道均表现出侵蚀-充填-废弃的旋回性。分析认为西沙碳酸盐台地周缘水道沉积物源来自西沙隆起和广乐隆起的碳酸盐台地和生物礁碎屑及由火成作用产生的火成岩碎屑。西沙-广乐碳酸盐台地水道相互贯通,构成台地-斜坡-深水的水道沉积体系,为碳酸盐岩、生物礁及火山碎屑向台地周缘输送提供了良好的通道。     

南海北部陆坡东沙海域海底丘状体气体与水合物分布

海底丘状体在天然气水合物发育区是一种常见的微地貌,对丘状体的研究有助于理解海底流体渗漏模式以及水合物的赋存规律。本文研究南海北部陆坡东沙海域天然气水合物发育区海底丘状体的特征及其与水合物的关系。研究所用的数据包括准三维多道地震数据、多波束数据以及浅地层剖面数据。在多波束海底地形图上,丘状体表现为局部的正地形,直径大约为300 m,高出周围海底约50 m。浅地层剖面上存在明显的声空白以及同相轴下拉现象,指示了海底丘状体气体的分布以及流体运移的路径。丘状体周围明显的BSR表明局部区域可能发育有水合物,水合物钻探结果也证实了这一推测。三维多道地震剖面上,丘状体正下方存在空白反射区域,这与泥火山的地震反射特征类似。但空白反射区域内存在强振幅能量,而且丘状体正下方存在连续的反射层,这表明该丘状体并非泥火山成因。综合钻探结果以及三维地震成像结果,认为水合物形成过程引起的沉积物膨胀以及海底碳酸盐岩的沉淀是形成该丘状体的主要原因。     

Distribution characteristics of delta reservoirs reshaped by bottom currents: A case study from the second member of the Yinggehai Formation in the DF1-1 gas field,Yinggehai Basin,South China Sea

The Dongfang1-1 gas field (DF1-1) in the Yinggehai Basin is currently the largest offshore self-developed gas field in China and is rich in oil and gas resources. The second member of the Pliocene Yinggehai Formation (YGHF) is the main gas-producing formation and is composed of various sedimentary types; however, a clear understanding of the sedimentary types and development patterns is lacking. Here, typical lithofacies, logging facies and seismic facies types and characteristics of the YGHF are identified based on high-precision 3D seismic data combined with drilling, logging, analysis and testing data. Based on 3D seismic interpretation and attribute analysis, the origin of high-amplitude reflections is clarified, and the main types and evolution characteristics of sedimentary facies are identified. Taking gas formation upper II (IIU) as an example, the plane distribution of the delta front and bottom current channel is determined; finally, a comprehensive sedimentary model of the YGHF second member is established. This second member is a shallowly buried “bright spot” gas reservoir with weak compaction. The velocity of sandstone is slightly lower than that of mudstone, and the reflection has medium amplitude when there is no gas. The velocity of sandstone decreases considerably after gas accumulation, resulting in an increase in the wave impedance difference and high-amplitude (bright spot) reflection between sandstone and mudstone; the range of high amplitudes is consistent with that of gas-bearing traps. The distribution of gas reservoirs is obviously controlled by dome-shaped diapir structural traps, and diapir faults are channels through which natural gas from underlying Miocene source rocks can enter traps. The study area is a delta front deposit developed on a shallow sea shelf. The lithologies of the reservoir are mainly composed of very fine sand and coarse silt, and a variety of sedimentary structural types reflect a shallow sea delta environment; upward thickening funnel type, strong toothed bell type and toothed funnel type logging facies are developed. In total, 4 stages of delta front sand bodies (corresponding to progradational reflection seismic facies) derived from the Red River and Blue River in Vietnam have developed in the second member of the YGHF; these sand bodies are dated to 1.5 Ma and correspond to four gas formations. During sedimentation, many bottom current channels (corresponding to channel fill seismic facies) formed, which interacted with the superposed progradational reflections. When the provenance supply was strong in the northwest, the area was dominated by a large set of delta front deposits. In the period of relative sea level rise, surface bottom currents parallel to the coastline were dominant, and undercutting erosion was obvious, forming multistage superimposed erosion troughs. Three large bottom current channels that developed in the late sedimentary period of gas formation IIU are the most typical.     

琼东南盆地陆坡区深水浊积水道的地震相特征

水道-天然堤体系作为油气储集圈闭日益引起沉积学家和勘探家的重视。地震相特征是识别深水水道的有效途径，本文基于高分辨率2D、3D地震资料的地震相分析，在琼东南盆地陆坡区深水盆地中识别出早中新世、上新世和第四纪多期深水水道体系。早中新世深水水道在地震剖面上具有强、弱振幅交替反射和相互叠置的地震反射特征，局部具有杂乱反射特点；上新世水道整体表现为强振幅，横向上连续或者半连续，纵向上为强振幅的叠加；第四纪水道在地震剖面上具有典型下切反射特点，该水道整体振幅相对较弱，但其水道轴部充填具有典型的强反射特征，这与世界典型地区的水道轴部粗粒充填强振反射一致。这几期深水水道都发育于低水位时期，为上部物源搬运引起的浊流事件而形成。     

Sequence stratigraphic analysis of Eocene Rock Strata,Offshore Indus,southwest Pakistan

In this study, seismic data from two wells (Pak G2-1 and Indus Marine-1C) and age diagnostic larger benthic foraminifera (LBF) within drill cuttings has been used for the first time to identify depositional sequences within the carbonates in the Offshore Indus Basin, Pakistan. The Offshore Indus is tectonically categorized as a passive continental margin where carbonates occur as shelf carbonates in the near offshore and on volcanic seamounts in deeper waters. Seismic data analysis has indicated the presence of minor faults and carbonate buildups above the igneous basement in the south. Patterns of the seismic reflections enabled definition of three seismic facies units identified as: Unit 1 basement, represented by chaotic, moderate amplitude reflection configuration; while parallel bedding and the drape of overlying strata is typical character of Unit 2, carbonate mound facies. The younger Miocene channels represent Unit 3. The diagnosis of Alveolina vredenburgi/cucumiformis biozone confirmed the Ilerdian (55–52 Ma) stage constituting a second order cycle of deposition for the Eocene carbonates (identified as Unit 2). The carbonate succession has been mainly attributed to an early highstand system tract (HST). The environmental conditions remained favorable leading to the development of keep-up carbonates similar to pinnacle buildups as a result of aggradation during late transgressive system tract and an early HST. The carbonate sequence in the south (Pak G2-1) is thicker and fossiliferous representing inner to middle shelf depths based on fauna compared to the Indus Marine-1C in the north, which is devoid of fossils. Three biozones (SBZ 5, SBZ 6 and SBZ 8) were identified based on the occurrence of LBF. The base of the SBZ 5 zone marks the larger foraminifera turnover and the Paleocene–Eocene (P–E) boundary. The LBF encountered in this study coincides with earlier findings for the P–E boundary. Our findings indicate that the entire Ilerdian stage ranges from 55.5 to 52 Ma that was the episode of warmer water conditions on the carbonate shelves leading to the diversification of K-strategist larger foraminifera. The larger foraminiferal assemblage encountered in this study confirms the findings. The possible indication of stratigraphic-combination traps, revealed as reflection terminations, make carbonate mounds in the south a potential exploration target.