基于潮位预测的潮汐校正方法在高分辨率单道地震调查中的应用

单道地震探测技术在海洋勘探各领域应用广泛,潮汐变化对高分辨率单道地震资料的质量有很大影响,尤其是对采集时间跨度较大的资料,在测线交点处存在严重的剖面不闭合现象。利用潮汐预测方法对高分辨率单道地震进行了潮汐校正,经过校正后的资料品质明显得到提升。通过对比不同测线交点处的剖面情况,剖面不闭合现象得到改善,同相轴的对应关系更好。实际应用结果表明,基于潮位预测的潮汐校正方法在高分辨率单道地震调查中的应用有效可靠。     

珠江口盆地西部新近纪高分辨率生物地层及海平面变化分析

珠江口盆地西部新近系主要为陆架浅海沉积环境,发育良好的海相砂岩储集层和多套储盖组合。因此,对这些砂体的成因及赋存位置的海平面变化研究至关重要。在有孔虫及钙质超微化石资料所建立的珠江口盆地西部新生代年代地层格架基础上,以有孔虫个体大于0.25mm的浮游有孔虫丰度和百分含量为依据,参照微体古生物化石带、岩性、电测和地震资料,总结出三级旋回边界和最大海泛面识别标志,从而提出具有国际对比意义的三级层序划分对比方案,对盆地内18口井进行了层序划分,识别出了2个完整的二级层序和15个三级层序。根据南海海域表层沉积物建立起的浮游有孔虫含量与水深的定量关系,得出量化古水深数据,辅以古生态成因相及特征沉积构造分析、海岸上超分析编制了海平面变化曲线,指出珠江口盆地西部新近系受拗陷阶段持续沉降影响,形成不同于海退型全球海平面变化的台阶式海侵特征。     

利用高分辨率水体反射地震资料研究吕宋海峡以东黑潮区混合

混合过程是海洋中普遍存在的一种形式, 对气候变化、物质分布等起到了重要作用。地震海洋学是近十多年发展起来的一门新兴学科, 被广泛应用到物理海洋学问题的研究中, 具有高空间分辨率的突出优点。文章利用反射地震资料, 通过斜率谱方法, 分别获得了吕宋海峡以东黑潮区湍流段与内波段的耗散率及扩散率。结果显示, 在剖面深度200~800m的平均耗散率为10 ^-7.0W·kg ^-1, 平均扩散率为10 ^-3.3m ²·s ^-1, 比大洋统计均值10 ^-5.0m ²·s ^-1高约1~2个量级, 与前人在吕宋海峡的观测结果相一致。湍流段和内波段的扩散率空间分布差异较大: 湍流段扩散率高值区对应强流区域, 推测这里是中尺度涡边缘, 其次中尺度不稳定过程引起扰动增强, 进而引起湍流混合的加强; 内波段扩散率高值区出现在吕宋岛弧附近, 推测是内波遇到岛弧地形发生破碎, 进而引起强的内波混合。     

跨南海西南次海盆OBS、多道地震与重力联合调查

对跨南海西南次海盆及两侧陆缘的一条1050km长的、包括海底地震(OBS)、长排列多道地震和重磁在内的综合地球物理探测剖面(CFT)进行了构造成像和研究。在多道地震成像基础上建立了CFT剖面初始速度模型, 进而通过初至波层析成像方法反演了CFT剖面的速度结构模型, 在重力异常资料的约束下建立了CFT剖面的综合地壳结构模型。讨论了沿CFT剖面出现的下地壳高速体、龙门海山的低密度物质等地质问题。结果表明, 下地壳高速层在北部陆坡、西南海盆和南部南沙地块均有分布, 厚度在0~4km之间, 可能与陆缘下地壳物质和地幔物质熔融混合, 以及深海盆海底扩张期间构造拉伸导致地幔蛇纹岩化有关。     

基于国产高分影像的海岸带盐田和水产养殖区图谱特征分析

海岸带区域水陆相接,盐业和水产养殖业发展迅速。本文基于国产高空间分辨率卫星遥感影像,对海岸带盐田和水产养殖区进行了全面的分析,总结了盐田和水产养殖区地物的颜色、色调、大小、形状、纹理、位置等遥感影像图谱特征,以期为盐田和水产养殖区遥感监测提供技术支撑。     

Middle to Late Cenozoic tectonic events in south and central Palawan (Philippines) and their implications to the evolution of the south-eastern margin of South China Sea: Evidence from onshore structural and offshore seismic data

Using recently gathered onland structural and 2D/3D offshore seismic data in south and central Palawan (Philippines), this paper presents a new perspective in unraveling the Cenozoic tectonic history of the southeastern margin of the South China Sea. South and central Palawan are dominated by Mesozoic ophiolites (Palawan Ophiolite), distinct from the primarily continental composition of the north. These ophiolites are emplaced over syn-rift Eocene turbidites (Panas Formation) along thrust structures best preserved in the ophiolite–turbidite contact as well as within the ophiolites. Thrusting is sealed by Early Miocene (∼20 Ma) sediments of the Pagasa Formation (Isugod Formation onland), constraining the younger limit of ophiolite emplacement at end Late Oligocene (∼23 Ma). The onset of ophiolite emplacement at end Eocene is constrained by thrust-related metamorphism of the Eocene turbidites, and post-emplacement underthrusting of Late Oligocene – Early Miocene Nido Limestone. This carbonate underthrusting at end Early Miocene (∼16 Ma) is marked by the deformation of a seismic unit corresponding to the earliest members of the Early – Middle Miocene Pagasa Formation. Within this formation, a tectonic wedge was built within Middle Miocene (from ∼16 Ma to ∼12 Ma), forming a thrust-fold belt called the Pagasa Wedge. Wedge deformation is truncated by the regionally-observed Middle Miocene Unconformity (MMU ∼12 Ma). A localized, post-kinematic extension affects thrust-fold structures, the MMU, and Late Miocene to Early Pliocene carbonates (e.g. Tabon Limestone). This structural set-up suggests a continuous convergent regime affecting the southeastern margin of the South China Sea between end Eocene to end Middle Miocene. The ensuing structures including juxtaposed carbonates, turbidites and shallow marine clastics within thrust-fold belts have become ideal environments for hydrocarbon generation and accumulation. Best developed in the Northwest Borneo Trough area, the intensity of thrust-fold deformation decreases towards the northeast into offshore southwest Palawan.     

Velocity structure in the South Yellow Sea basin based on first-arrival tomography of wide-angle seismic data and its geological implications

The South Yellow Sea basin is filled with Mesozoic–Cenozoic continental sediments overlying pre-Palaeozoic and Mesozoic–Palaeozoic marine sediments. Conventional multi-channel seismic data cannot describe the velocity structure of the marine residual basin in detail, leading to the lack of a deeper understanding of the distribution and lithology owing to strong energy shielding on the top interface of marine sediments. In this study, we present seismic tomography data from ocean bottom seismogra...