南极罗斯海重力场特征及莫霍面深度反演

本文基于中国南极考察第30航次、第32航次所获得的实测重力资料,结合NGDC资料,开展12个航次重力场数据的平差融合工作,全部386个交点平差后标准差减小为±1.53×10−5 m/s2,与卫星重力差值平均值为1.49×10−5 m/s2,均方差为±3.81×10−5 m/s2,并在此基础上采用频率域界面反演法计算莫霍面深度。研究发现,与沉积盆地对应重力异常低值相悖,在罗斯海北部盆地、维多利亚地盆地、中央海槽、东部盆地4个主要盆地腹地却表现为重力异常高值,跨度达100 km以上。莫霍面深度分布整体呈南深北浅之势,范围为10~28 km。伴随着罗斯海西部盆地的多次拉张及岩浆活动,该区域的地壳厚度和莫霍面深度高值和低值相间分布,并表现出越来越大的差异性。综合剖面结果表明,罗斯海重力异常值的长波长变化与莫霍面的起伏呈正相关关系,但是反演的莫霍面深度与区域重力场特征并非完全对应,所以岩浆底侵和地壳侵入仍不足以导致罗斯海盆地的重力异常或盆地几何形状。     

Aegir脊及邻区重磁异常及构造特征

为研究北极地区挪威海内Aegir脊及邻区断裂构造特征，为北极地区油气勘探提供方向，在斯克里普斯海洋研究所发布的研究区重力数据（网格数据）基础上填充最新船测数据，对已有重磁资料进行异常分离、滑动平均和重磁场边界识别。目前，研究区的特征断裂和构造单元划分尚不清楚。根据异常极值带、异常带走向、异常梯度带变化程度等，对研究区进行了断裂识别和构造单元划分。研究表明：重磁异常特征呈NNE-NW-NE向展布，重力异常呈现高低分带，反映出该区基底隆坳相间的格架。根据重磁异常与断裂对应关系，识别出4个构造走向和7条主要断裂，划分出Mohns脊、扬马延微陆块、东扬马延断裂带、西扬马延断裂带、Aegir脊、东扬马延深海盆地和挪威深海盆地等7个构造单元。     

南沙海域重力场的研究——利用卫星重力场探求不同深度物质源的重力作用

本文用不同阶次的卫星重力场作为区域场,与地面观测的重力场作对比,得出剩余重力场,根据剩余重力场探求不同深度物质源的重力作用的方法,对南沙海域的重力场和几个具有显著重力异常特征的地区物质源的深度进行了探讨。     

东海陆架盆地与冲绳海槽盆地构造活动的差异性

东海陆架盆地和冲绳海槽盆地在区域地质构造上虽然同属下沉区,但它们的重力异常（其中包括布格异常,空间异常和均衡异常）,地貌特征沉积环境,地壳类型,应力分布,构造活动,成因机制上均存在着本质的差别,从而揭示了两者决不是简单的“块体”下沉,而是两个性质完全不相同的构造单元。     

东海陆架盆地与冲绳海槽盆地构造活动的差异性

东海陆架盆地和冲绳海槽盆地在区域地质构造上虽然同属下沉区,但它们的重力异常（其中包括布格异常、空间异常和均衡异常）、地貌特征、沉积环境、地壳类型、应力分布、构造活动、成因机制上均存在着本质的差别,从而揭示了两者决不是简单的“块体”下沉,而是两个性质完全不相同的构造单元。     

几种卫星测高海洋重力场模型精度比较分析

以中国南海部分海域作为试验区,依据测区船载重力测量结果分别对S&S V28.1、S&S V29.1、DTU15和DTU17卫星测高海洋重力场模型开展了精度评估与分析工作。首先利用EIGEN6C4超高阶位系数模型计算得到的参考重力异常,使用多项式拟合技术对船载重力异常进行了长波误差改正;然后借鉴3σ准则进一步控制船载重力测量结果质量;最后以RMS作为精度主要评价指标,完成了对4种海洋重力场模型精度评估。结果表明,4种海洋重力场模型检核精度整体相当,其中S&S V29.1检核精度略高于S&S V28.1,4种重力异常模型在试验海域精度大致在1.5~6mGal之间。试验结论对于后续重力场模型应用具有一定参考价值。     

海空重力测量及应用技术研究进展与展望(二):传感器与测量规划设计技术

分3个阶段全面分析总结了海空重力测量传感器的发展进程及研究现状,简要介绍了作为海空重力测量重要组成部分的定位系统的技术发展状况,分析展望了海空重力仪稳定性测试与评估技术的发展前景,详细论述了海洋重力场特征的分析方法及研究方向,分析讨论了海洋重力场信息应用需求与海空重力测量规划设计的内在联系及海洋重力测线布设技术的研究进展。     

GT-1M 海洋重力仪与KSS31M 海洋重力仪的对比

为了检验俄罗斯、加拿大合作生产的GT-1M海洋重力仪与德国KSS31M海洋重力仪的工作性能,验证GT-1M重力数据的可靠性,将GT-1M采集的3条重力剖面与KSS31M重力仪采集的重力测网进行了对比分析。结果显示:GT01剖面与26条KSS31M重力测线的交点差均值为0.31mGal,交点差均方根为2.51mGal;GT02剖面与11条KSS31M重力测线的,交点差均值为–0.78mGal,交点差均方根为1.97mGal;全部交点差均值为–0.01mGal,均方根(RMS)为2.32mGal。GT01剖面与KSS31M测网网格化切割的剖面的变化趋势一致,重力变化幅值基本吻合,相关系数为0.98;而GT02剖面位于KSS31测网边缘,网格化切割的KSS重力剖面不能反应真实的重力场,虽然GT02剖面变化趋势一致,但相关系数仅为0.94,在相位上也明显有误差。考虑到测网位于海底地形崎岖的深水区,而且两次测量时间间隔达3a,因此GT-1M重力仪测试的结果还是基本与KSS31M重力仪吻合的,数据是可靠的。该分析结果对今后的重力测量工作有参考价值。     

基于SINS/DGPS的捷联式航空重力矢量测量

国防科学技术大学研制成功了我国首套具有自主知识产权的捷联式航空重力测量系统SGA-WZ01。该重力测量系统由捷联式惯性导航系统(SINS)和差分全球定位系统(DGPS)组成。2012年4~5月,在南海某海域进行了飞行试验以测试这一新型重力仪的精度。描述了该系统的构成和数据处理过程,在数据处理中应用了全球重力场模型对重力测量结果进行校正。试验结果表明,该系统不仅可用于重力标量测量,还可用于矢量测量。重复测线的数据表明了该系统测得的重力异常的重复性可达到1.5m Gal,经过全球重力场模型校正之后北向分量的重复性为7.46m Gal,东向分量的重复性为4.46m Gal。     

南海沙巴—巴拉望边缘重力异常及深部构造控制

南海富烃区的东南部边缘被北西－南东走向的构造线分割成一系列区段，各区段具有鲜明的特征，重力形态往往发生突然变化。其中沙巴段的西南以廷贾（Tinjar)或西巴兰（West Baram)构成线为界，东北与苏禄海西南边缘的巴拉巴克构造线邻接。这部分最显著的特征是沿着距岸约150km的沙巴海槽伴生的自由空间重力异常极低。地震反射资料显示，前积沉积和重力驱动推覆体所产生的负荷使伸展的南海陆壳下陷到局部均衡面之下，产生了类似前陆盆地的海槽，海槽中的沉积速率低于沉降速率。负荷体本身则位于局部均衡面之上，部分受下伏地壳和岩石圈的刚性所支持。深部的晚第三纪沉积盆地就位于布格重力和自由空间重力高带的侧翼上。穿过沙巴海岸的重力值降低，因此，大致处于均衡补偿的克罗克（Crocker）山脉（包括Mt Kinabalu)很可能位于较弱的岩石圈之上。而和沙巴海沟相伴生的自由空间重力异常比根据其水体厚度所计算的异常要小，这预示着海槽轴线下面的地壳减薄，这不是一个正常的前陆盆地特征，因此推断地壳减薄是在盆地形成前就出现的。在沙巴海槽中最显著的是呈NE－SW走向的平行的重力异常和地貌特征，它们与海槽中早第三纪地质走向不一致，因此它们是受南海岩石圈和地壳中原有组构的控制。沙巴地区的第三纪构造重组就是以这种假设为基础的，即南海边缘在老第三纪的陆架裂开时所形成的裂谷盆地中的沉积物是这个地区富烃资源的主要来源。     

南海北部含油气构造上方化探异常研究

在南海北部利用地球化学方法作为油气勘探的一种辅助手段。在6个航次中采集了沉积物、底层海水及海面大气样品，测定了近50种化探指标，并采用稳健统计方法进行了数据处理和异常圈定。化探结果在油气藏上方发现了清晰的、具不同指标组合的综合化探异常，与邻近空构造形成鲜明的对照。圈闭顶部的块状异常和圈闭周绿的环状、半环状异常是下伏油气藏的良好指示，而剖面上呈锯齿状、平面上呈线状的异常则与断裂带有关。实践表明，建立已知油气藏上方的化探异常模式及解剖已知空构造上方的地球化学特征对于指导本区或邻区的化探异常评价是十分必要的。     

赤道几内亚里奥穆尼盆地构造演化特征及油气勘探前景

应用盆地原形分析、区域地震资料解释和石油地质综合分析等方法,探讨了赤道几内亚里奥穆尼盆地构造演化和成藏条件。研究结果表明,该盆地构造演化经历了裂谷、过渡—漂移和裂后被动大陆边缘3个阶段,主要充填了中新生代沉积地层,中生界白垩系主要发育2套烃源岩,为裂谷期的湖相泥页岩和过渡—早期漂移期的海相泥页岩,已发现的油气主要储集在上白垩统浊积砂体。盐构造和重力滑动构造是油气成藏的主控因素,在区域上,油气主要分布在盆地的中带,该带勘探程度低,成藏条件优越,是油气聚集的有利场所,尤其盐构造与重力滑动构造区具有较大油气勘探潜力。     

胶莱盆地构造单元划分及其特征

根据胶东地区重力反演计算结果，结合地质资料，对胶莱盆地内部单元进行划分，并进一步结合沉积特征，对各构造单元特征进行了初步的总结。     

南黄海盆地地质演化及构造样式地震解释

南黄海盆地奠基于前南华纪变质基底之上,盆地演化历经南华纪—早、中三叠世海相地层发育期、晚白垩世—古近纪箕状断陷发育期和新近纪—第四纪坳陷发育期,为一典型地台—断陷-坳陷多层结构的复合盆地。受不同时期地质营力及区域应力场变化的影响,南黄海盆地形成多种构造样式,可分为伸展构造、挤压构造、反转构造和底辟构造4类,前3类构造样式是地壳水平运动的结果,后一类是地壳垂直运动的结果。     

Identification of mantle and lithospheric components of the gravity field by isostatic gravity anomalies

All anomalous masses of the Earth are reflected in the free air gravity anomalies and the geoidal undulations. The low viscosity of the asthenosphere significantly reduces the possibility of existence of density inhomogeneities in the layer. This fact provides some physical basis for the separation of the gravity field anomalies. It has been shown by power spectrum analysis of the free air anomalies and gravity field of isostatically compensated model of the lithosphere for the North Atlantic and adjacent areas of America, Europe and Mediterranean, that the attraction of isostatically compensated model is significant for any wave length of the field. It causes significant error in the interpretation if long wavelength constituents of the free air gravity anomalies are considered as a field of deep anomalous masses. The isostatic anomalies und isostatic geoid are free from the influences of isostatically compensated lithosphere. The characteristic feature of the isostatic anomalies power spectrum is a pronounced minimum at the wavelength of about 1000 km. The relative homogeneity of the asthenosphere may explain this minimum. It means that principal density inhomogeneities of the Earth's interior are separated by the asthenospheric layer. Such a minimum has not been observed at the power spectrum of free air anomalies being masked by corresponding wavelength of the field of isostatically compensated lithosphere. Isostatic anomalies that reflect the differences between the real structure of the lithosphere and its isostatically compensated model have wavelengths less than 1000 km. Isostatic anomalies with the wavelength more than 1000 km reflect the attraction of density inhomogeneities situated under the level of isostatic compensation. The basic features of power spectrum of isostatic anomalies are the same for oceanic and continental areas. The method based on Kolmogorov-Wiener filtration which consideres statistical characteristics of the field has been developed to divide the isostatic gravity anomalies into lithosphere and mantle components. For the North Atlantic and adjacent areas the field of mantle inhomogeneities has been determined.     

Basement-involved faults and deep structures in the West Philippine Basin: constrains from gravity field

To reveal the basement-involved faults and deep structures of the West Philippine Basin (WPB), the gravitational responses caused by these faults are observed and analyzed based on the latest spherical gravity model: WGM2012 Model. By mapping the free-air and Bouguer gravity anomalies, several main faults and some other linear structures are located and observed in the WPB. Then, by conducting a 2D discrete multi-scale wavelet decomposition, the Bouguer anomalies are decomposed into the first- to eighth-order detail and approximation fields (the first- to eighth-order Details and Approximations). The first- to third-order Details reflect detailed and localized geological information of the crust at different depths, and of which the higher-order reflects gravity field of the deeper depth. The first- to fourth-order Approximations represent the regional gravity fields at different depths of the crust, respectively. The fourth-order Approximation represents the regional gravity fluctuation caused by the density inhomogeneity of Moho interface. Therefore, taking the fourth-order Approximation as input, and adopting Parker-Oldenburg interactive inversion, We calculated the depth of Moho interface in the WPB. Results show that the Moho interface depth in the WPB ranges approximately from 8 to 12 km, indicating that there is typical oceanic crust in the basin. In the Urdaneta Plateau and the Benham Rise, the Moho interface depths are about 14 and 16 km, respectively, which provides a piece of evidence to support that the Banham Rise could be a transitional crust caused by a large igneous province. The second-order vertical derivative and the horizontal derivatives in direction 0° and 90° are computed based on the data of the third-order Detail, and most of the basement-involved faults and structures in the WPB, such as the Central Basin Fault Zone, the Gagua Ridge, the Luzon-Okinawa Fault Zone, and the Mindanao Fault Zone are interpreted by the gravity derivatives.     

Crustal analysis of the Ulleung Basin in the East Sea (Japan Sea) from enhanced gravity mapping

To facilitate geological analyses of the Ulleung Basin in the East Sea (Japan Sea) between Korea and Japan, shipborne and satellite altimetry-derived gravity data are combined to derive a regionally coherent anomaly field. The 2-min gridded satellite altimetry-based gravity predicted by Sandwell and Smith [Sandwell DT, Smith WHF (1997) J Geophys Res 102(B5):10,039–10,054] are used for making cross-over adjustments that reduce the errors between track segments and at the cross-over points of shipborne gravity profiles. Relative to the regionally more homogeneous satellite gravity anomalies, the longer wavelength components of the shipborne anomalies are significantly improved with minimal distortion of their shorter wavelength components. The resulting free-air gravity anomaly map yields a more coherent integration of short and long wavelength anomalies compared to that obtained from either the shipborne or satellite data sets separately. The derived free-air anomalies range over about 140 mGals or more in amplitude and regionally correspond with bathymetric undulations in the Ulleung Basin. The gravity lows and highs along the basin’s margin indicate the transition from continental to oceanic crust. However, in the northeastern and central Ulleung Basin, the negative regional correlation between the central gravity high and bathymetric low suggests the presence of shallow denser mantle beneath thinned oceanic crust. A series of gravity highs mark seamounts or volcanic terranes from the Korean Plateau to Oki Island. Gravity modeling suggests underplating by mafic igneous rocks of the northwestern margin of the Ulleung Basin and the transition between continental and oceanic crust. The crust of the central Ulleung Basin is about a 14–15 km thick with a 4–5 km thick sediment cover. It may also include a relatively weakly developed buried fossil spreading ridge with approximately 2 km of relief.     

南海东北部的断裂分布及其构造格局研究

通过对南海东北部重磁异常的分析和处理,结合珠江口盆地、潮汕坳陷等地区的综合地质地球物理研究成果,根据研究区的重磁异常特征划分了4个异常区。应用地球物理数据处理方法,推断了该区的主要断裂35条,其主要走向为NW、NE、NEE向及S-N向4组。综合各方面研究成果在该区划分了7个构造单元。依据地震剖面、物性资料和重磁资料的分析,对南海东北部地区中生界的地层标定、构造与结构特征有了新的认识,研究了该地区前第三系基底和中生界的分布,并对南海东北部构造演化进行了探讨。     

台西南盆地地质构造特征及油气远景

本文从盆地的基本地质特征入手,分析了台西南盆地的地层、沉积、构造特征及油气条件,在进行盆地的定性分析的基础上,对盆地内的次级构造单元进行了类比,对盆地的含油气远景进行了评价,提出了该盆地的油气勘探方向。